Given the increasing costs to power and cool data centers, IT and Facility managers of enterprise and cloud data centers want to maximize capacity utilization and reduce total cost of operations. However this has been challenging given the lack of fine grained instrumentation and visibility into server and rack level power consumption resulting in over-provisioning of racks and costly expansions despite unused capacity.

With Intel® Xeon® 5500 series, we introduced Intel® Intelligent Power Node Manager that provides server level power monitoring and policy based power capping. Since power and cooling constraints exist at rack, row, room and PDU level, we also released Intel® Data Center Manager to enable ISVs to realize Node Manager benefits at data center level with reduced investment.

Intel® DCM software development kit (SDK) provides power and thermal monitoring and management for servers, racks and groups of servers in data centers using Intel® Xeon instrumentation. Management Console Vendors (ISVs) and System Integrators (SIs) can integrate Intel® DCM into their console or command-line applications and provide high value power management features to IT organizations.

IT organizations facing power and cooling challenges can benefit from:

• Increased rack density within space, power and cooling constraints through power control
• Reduced capital costs by right-sizing power and cooling infrastructure based on actual power
• Reduced operations costs by eliminating worst-case head-room during provisioning

Intel® DCM features include:

• Built-in policy based heuristics engine maintains group power and dynamically responds to changing loads
• Designed as an SDK to integrate into existing management software products
• Scales to thousands of nodes support in large data centers
• Manages across system vendors through use of standard IPMI and DCMI Power Management support
• Supports integration with Smart PDU meters for servers without Node Manager to provide a unified view

If you are at IDF in San Francisco Sep 22-24, 2009, stop by following sessions to learn more about Intel® DCM and see proof-of-concepts and meet with end users who benefited from this.

• PDCS003 - Cloud Power Management with Intel® Micro-architecture (Nehalem) Processor-based Platforms
• ECTS0004 - Improving Data Center Efficiency with Intel® Xeon® Processor Based Instrumentation

There are also several demos in the showcase area that showcase the technologies from multiple partners.

I will be at IDF co-presenting PDCS003 - stop by after the class with your questions and thoughts about Intel® DCM.
See you at IDF.

--Susmita

Have you ever had one of those MacGuyver moments? You know – you have a problem to solve and a collection of items at your disposal, and if you use can figure out how to use those items, you can save the day.

Earlier this year Intel, HP, IBM, Lawrence Berkeley Labs, Emerson Network Power & Wunderlich-Malec collaborated on a California Energy Commissions sponsored MacGuyver-ish project call Advanced Cooling Environment (ACE) to solve an issue that many data centers face – overcooling their data centers beyond the needs of the servers and other IT equipment running inside of the facility.  You see, IT equipment is designed to run within a temperature envelope. If the air coming into the server is warmer than the envelope, you run the risk of overheating. If the air coming into the server is colder than the envelope, you are spending too much money on cooling the air, which does nothing other than needlessly increase the cost of operating the data center and reduces the energy efficiency as well.

The team surveyed the items at its disposal and determined that they could link data from the front panel temperature sensors (server instrumentation) on the servers to the control systems of the computer room air handlers (CRAHs – essentially air conditioners) via standard data center management communication protocol.   The CRAHs could then dynamically adjust the speed of the fans and the temperature of the air to the requirements of the servers. The results: servers received the appropriate temperature air, power costs for cooling went down and the energy efficiency of the data center went up.  Problem solved….and they didn’t even use a paper clip or shoestring.  The real beauty of the project is that all of the items used are commercially available today for you to instrument your data center and improve the energy efficiency of your operation.

To learn more about ACE at the upcoming Intel Developer Conference in San Francisco, check out the “ECOS003 Advanced Cooling Environment (ACE) Technology: Controlling Data Center Cooling with Servers” or stop by the ACE demo in the Eco-Tech Zone of the Tech Showcase.

I would like to elaborate on the topic energy vs. power management in my previous entry.

Upgrading the electrical power infrastructure to accommodate additional servers is not an option in most data centers today.  Landing additional servers at a facility that's working at the limit of thermal capacity leads to the formation of hot spots, this assuming that electrical capacity limits are not reached first with no room left in certain branch circuits.

There are two types of potentially useful figures of merit, one for power management and one for energy management.  A metric for power management allows us to track operational "goodness", making sure that power draw never exceeds limits imposed by the infrastructure.  The second metric tracks power saved over time, which is energy saved.  Energy not consumed goes directly to the bottom line of the data center operator.

To understand the dynamic between power and energy management let's look at the graph below and imagine a server without any power management mechanisms whatsoever.  The power consumed by that server would be P(unmanaged) regardless of any operating condition.  Most servers today have a number of mechanisms operating concurrently, and hence the actual power consumed at any given time t is P(actual)(t).  The difference P(unmanaged) - P(actual) is the power saved.  The power saved carried over time t(1) through t(2) yields the energy saved.

Please note that a mechanism that yields significant power savings may not necessarily yield high energy savings.  For instance, the application of Intel(r) Dynamic Power Node Manager (DPNM) can potentially bring power consumption by over 100 watts, from 300 watts at full load to 200 watts in a dual-socket 2U Nehalem server that we tested in our lab.  However, if DPNM is used as a guard rail mechanism, to limit power consumption if a certain threshold is violated, DPNM may never kick in, and hence energy savings will be zero for practical purposes.  The reason why we do this is because DPNM works best only under certain operating conditions, namely high loading factors, and because it works through frequency and voltage scaling, it brings a performance tradeoff.

Another useful figure of merit for power management is the dynamic range for power proportional computing.  Power consumption in servers today is a function of workload as depicted below:

The relationship is not always linear, but the figure illustrates the concept.  On the x-axis  we have the workload that can range from 0 to 1, that is, 0 to 100 percent.  P(baseline) is the power consumption at idle, and P(spread) is the power proportional computing dynamic range between P(baseline) and power consumption at 100 percent workload.  A low P(baseline) is better because it means a low power consumption at idle.  For a Nehalem-based server, P(baseline) is roughly 50 percent of power consumption at full utilization, which is remarkable, considering that it represents a 20 percent over the number we observed for the prior generation, Bensley-based servers.  The 50 percent figure is a number we have observed in our lab for a whole server, not just the CPU alone.

If a 50 percent P(baseline) looks outstanding, we can do even better for certain application environments such as load-balanced front end Web server pools and the implementation of cloud services through clustered, virtualized servers.  We can achieve this effect through the application of platooning.  For instance, consider a pool of 16 servers.  If the pools is idle, all the servers except one can be put to sleep.  The single idle server is consuming only half the power of a fully loaded server, consuming one half of one sixteenth of the cluster power.  The dormant servers still draw about 2 percent of full power.  Hence, after doing the math, the total power consumption for the cluster at idle will be about 8 percent of the full cluster power consumption.  Hence for a clustered deployment, the power dynamic range has been increased from 2:1 for a single server to about 12:1 for the cluster as a whole.

In the figure below note that each platoon is defined by the application of a specific technology or state within each  technology.  This way it is possible to optimize the system behavior around the particular operational limitations of the technology.  The graph below is a generalization of the platooning graph in the prior article.  For instance, a power capped server will impose certain performance limitations to workloads, and hence we assign non time critical workloads to that platoon.  By definition, an idling server cannot have any workloads; the moment a workload lands on it it's no longer idle, and its power consumption will rise.

The CPU is not running in any of the S-states than S0.  The selection of a specific state depends on how fast that particular server is needed online.  It takes longer to bring up a server online in the lower energy states.  Servers in G3 may actually be unracked and put in storage for seasonal equipment allocation.

A virtualized environment makes it easier to rebalance workloads across active (unconstrained and power capped) servers.  If servers are being used as a CPU cycle engines, it may be sufficient to idle or put to sleep the subset of servers not needed.

The extra dynamic power range comes at the expense of instituting additional processes and operational complexity.  However, please note that there are immediate benefits in power and energy management accrued through a simple equipment refresh.  IBM reports an 11X performance gain for Nehalem-based HS22 blade servers versus the HS20 model only three years old.  Network World reports a similar figure, a ten-fold increase in performance, not just ten percent.

I will be elaborating on some of these ideas at the PDCS003 Cloud Power Management with the Intel(r) Nehalem Platform class at the upcoming Intel Developer Forum in San Francisco on the week of September 20th.  Please consider yourself invited to join me if you are planning to attend this conference.

Japan announced today that it has emerged from recession, following Germany and France’s announcements last week that their economies also grew in the second quarter. 

Moody’s Economy.com Business Confidence survey shows that confidence has been steadily increasing since March ‘09.

For the first time since September ’08, “Economic Recovery” nudges above “Economic Crisis” in Google Search Volume in early August. 

In addition to this, economic forecasts (WW GDP, US GDP, and EU GDP) point to a recovery over the next 6 months.  A couple of quotes:

• The direction of real GDP is even expected to turn from negative to positive in the current quarter. The academic arbiters of the business cycle at the National Bureau of Economic Research will eventually proclaim that the Great Recession ended sometime this summer.
         Moody’s Economy.Com – July 7, 2009
• The global economy is beginning to pull out of a recession unprecedented in the post–World War II era
         International Monetary Fund, imf.org – July 8, 2009

So, why am I bombarding this blog with various optimistic economic data? Because if we really are pulling out of the abyss, I’m worried that many companies out there are sitting on servers that will not be ready for the increased demand right around the corner.         

John Gantz, IDC Vice President in his keynote speech at the start of this year’s CIO Summit in Auckland was quoted as saying there will be an unprecedented amount of IT-driven change in the next four years.  He projected that there will be a three-fold rise in mobile users and information will grow five-fold, resulting in heightened levels of security and privacy and questions on which data to store or throw away. He also mentioned that the number of interactions between people on networks will grow eight times.

So this got me thinking… Is your company looking to differentiate and go after more market share while your competitors are hunkered down and not investing in the downturn? My guess is that there are a lot of IT managers being asked to support more social media, offer more SaaS, deploy more virtual machines, and support more real time analytics to get a leg up on the competition.  My gut tells me that it will be hard to do all of this with older servers that were put into another year of extended warranty because that felt like the right move when the proverbial economic s**t hit the fan last year. 

It’s critical to be prepared for when the recovery comes, and data points to an economic turnaround happening now – are you positioning your department to own it when it arrives?

Bryce

I wrote a while back about how the Xeon 7400(Dunnington) processor series compared to RISC. Since then I have shared information through other blog posts and sharing content about how Xeon 7400 and Xeon 5500 will compare to both SPARC and POWER.

Xeon 7400 and Xeon 5500 are the current products shipping into the marketplace today. I.M.H.O they offer a pretty compelling alternative from both a performance and TCO perspective Vs SPARC and POWER. But I will not try and repeat all the reasons here

What I wanted to share with you was some thoughts about what the next product to succeed Xeon 7400 will bring to the RISC party. Nehalem-EX is the code-name for our next generation of product designed to serve workloads currently serviced by Xeon 7400 today (i.e. Database, ERP,  BI etc). EX btw is what we all would traditionally call MP or multi processor servers

Don't stop reading now, here is why I'm EXCITED about what Nehalem-EX will bring to the RISC party.

My excitement is actually based on real customer discussions about what Nehalem-EX will do for them and why it delivers some new stuff (my code for features and benefits) which they see as a pre-requisite to make the move from RISC to Xeon. For some customers the TCO and performance of  products have been enough to convince them to move. For some other customers there are still some checkboxes remaining which I believe Nehalem-EX will address

Here is a snapshot of some of the cool new stuff which is actually convincing customers (from some real deals that I have worked)

1. Improved bandwidth. Up to 9 times memory bandwidth of previous generations
2. Introduction of Quickpath Interconnects to the EX systems
3. Add new RAS features previously seen on Itanium products to Xeon products
4. Significant improvement in performance vs previous generations e.g. Database 2.5xe
5. More scalable platforms through 8 OEMs offering >8S. These platforms are key to manage large databases and for large scale consolidation
6. Mainframe class availability in scalable platforms

For more information check out the press briefing from May. See more the details in the presentation

Nehalem-EX goes into production later this year and I am pretty excited about how it will change the game. What do you think?

There are two technologies available to regulate power consumption in the recently introduced Nehalem servers using the Intel® Xeon® processor 5500 series.  The first is power proportional computing where power consumption varies in proportion to the processor utilization.  The second is Intel® Dynamic Power Node Manager (DPNM) technology which allows the setting of a target power consumption when a CPU is under load.  The power capping range increases with processor workload.

An immediate benefit of the Intel® Dynamic Node Manager (DPNM) technology is the capability to balance and trade off power consumption against performance in deployed Intel Nehalem generation servers.  Nehalem servers have a more aggressive implementation of power proportional computing where idle power consumption can be as small as 50 percent of the power under full load, down from about 70 percent in the prior (Bensley) generation.  Furthermore, the observed power capping range under full load when DPNM is applied can be as large as 100 watts out for a two-socket Nehalem server with the Urbanna baseboard observed in the lab to draw about 300 watts under full load.  The actual numbers you will obtain depend on the server configuration: memory, number of installed hard drives and the number and type of processors.

Does this mean that it will be possible to cut the electricity bills by one third to one half using DPNM?  This is a bit optimistic.  A typical use case for DPNM is as a "guard rail".  It is possible to set a target not to exceed for the power consumption of a server as shown in the figure below.  The red line in the figure represents the guard rail.  The white line represents the actual power demand as function of time; the dotted line represents the power consumption that would have existed without power management.

Enforcing this power cap brings operational flexibility: it is possible to deploy more servers to fit a limited power budget to prevent breakers from tripping or to use less electricity during peak demand periods.

There is a semantic distinction between energy management and power management.  Power management in the context of servers deployed at a data center refers to a capability to regulate the power consumption at a given instant.  Energy management refers to the accumulated power saved over a period of time.

The energy saved through the application of DPNM is represented by the area between the dotted line and the white graph line below; the power consumed by the server is represent by the area under the solid white graph line.  Since power capping is in effect during relatively short periods, and when in effect the area between the dotted line and the guard rail is relatively small, it follows that the energy saved through the application of DPNM is small.

One mechanism for achieving significant energy savings calls for dividing a group of servers running an application into pools or "platoons".  If servers are placed in a sleeping state (ACPI S5 sleep) during periods of low utilization it is possible to bring their power consumption to less than 5 percent of their peak power consumption, basically just the power needed to keep the network interface controller (NIC) listening for a wakeup signal.

As the workload diminishes, additional servers are moved into a sleeping state.  The process is reversible whereby servers are taken from the sleeping pool to an active state as workloads increase.  The number of pools can be adjusted depending on the application being run.  For instance, it is possible to define a third, intermediate pool of power capped servers to run lower priority workloads.  Capped servers will run slightly slower, depending on the type of workload. 

Implementing this scheme can be logistically complex.  Running the application in a virtualized environment can make it considerably easier because workloads in low use machines can be migrated and consolidated in the remaining machines.

We are conducting experiments to ***** the potential for energy savings.  Initial results indicate that these savings can be significant.  If you, dear reader have been working in this space, I'd be more than interested in learning about your experience.

If this topic is of interest to you, please join us at the Intel Development Forum in San Francisco at the Moscone Center on September 22-24.  I will be facilitating course PDCS003, "Cloud Power Management with the Intel(r) Xeon(r) 5500 Series Platform."  You will be the opportunity to talk with some of our fellow travelers in the process of developing power management solutions using Intel technology ingredients and get a feel of their early experience.  Also please make a note to visit booths #515, #710 and #712 to see demonstrations of early end-to-end solutions these folks have put together.

I was out at HP Tech Forum last week and had a chance to catch up on all the latest technology advancements with HP and Intel. What I saw was staggering, over 17 new HP-Intel designs, the HP Performance Optimized Datacenter (POD), and lot's more that I will be sharing with you in coming days as I add more video from the event and help to tell the story if you couldn't be there. First off, I caught up with John McAtee from Intel's HP account team. He was showing a cool demonstration on why now is the right time to invest in XEON 5500 processor series technology. Check out this video and find out how you can start saving in your datacenter today !

If you want more information on how the XEON 5500 processor series can starting saving in the datacenter, check out this ROI Calculator tool. Also, if you are looking for detailed information or are just looking to gain more knowledge, you can always "Ask The Professor" in our Server Learning Center.

Non-x86 RISC architectures, Power or SPARC, have been used in high end business critical virtualization solutions for a long while now. These come with a vertical stack of solution including the hardware, software, manageability tools and services provided by one vendor. This often leads to lock-in to the proprietary virtualization solution and services, and can be expensive from an end user perspective.

There are reasons why companies that can afford RISC based solutions have subscribed to it. This has been mainly due to Reliability, Availability and Serviceability (RAS) features, scalability and dedicated resources for quality of service (QoS) and isolation.

The world of virtualization however has significantly changed in the last 5 years. x86 based hardware and software products today offer well accepted and high performance virtualization solution. With the eminent availability of highly scalable and resilient Nehalem-EX products with 16-threads per socket and extensive RAS capabilities in the near future, the line between an expensive RISC solution and x86 based virtualization solution could blur further.

From an end user’s perspective, Nehalem-EX could provide sufficient capabilities that they have come to expect out of a RISC based virtualization infrastructure. Looking at it:

• Hardware partitioning of Nehalem-EX platform would be possible. Along with this OS virtualization and full commercial hypervisor support for logical partitioning already exists on Xeon processors.
• Nehalem-EX hardware infrastructure allows software ecosystem to deliver capacity on demand. For example extra CPU capacity can be dynamically added as needed. Moreover VM migration and policy based load balancing capabilities that already exist in commercial hypervisors complement this and provides IT easy methods to manage capacity at the datacenter level.
• Memory can be dedicated by not oversubscribing the available physical memory.
• CPUs can be dedicated by creating CPU affinity.
• Dedicated I/O assignment is possible using VT for Directed I/O. It can also restrict DMA access from devices to certain areas in memory, increasing isolation and system reliability.
• Single Root IO Virtualization feature would be available as part of Intel VT for connectivity in the networking devices. This allows a single NIC to be shared amongst multiple VMs directly, while isolating the traffic from a NIC queue to a VM for better reliability. Per VM bandwidth allocation can also be supported.
• Nehalem EX adds virtualization feature that could help increase VM performance in a processor oversubscribed environment with high system utilization.
• Nehalem-EX will add new reliability, availability and serviceability (RAS) such as Machine Check Architecture (MCA) Recovery that allows error detection, error recovery and VM isolation.
• Inherent power technologies in the CPU, Turbo mode, and Dynamic Power Node Manager for system wide power capping all deliver IT the essential keys to balance power and performance.

While Nehalem-EX measures up to the infrastructure needs, it also enables horizontal solution that would allow customers to take advantage of best of breed software from the virtualization ecosystem thus reducing lock-in. This could result in faster innovation leading to an array of choices for business critical virtualization.

Based on http://www.itjungle.com/tfh/tfh042808-story03.html, a Power virtualization solution with Power6 based 4 Socket P550 box (~$93,000) and PowerVM Enterprise Edition for large system ($1,969 per core, with $220 per year on the maintenance) will totally cost an enterprise $109,000, just in one server acquisition.

While pricing of NHM-EX 4S system is not available, approximating a cost using current 4-Socket Intel server pricing and commercial VMM software would suggest that Intel based solution could cost at-least 50% less in just infrastructure. Other savings like not requiring specialized RISC based hardware, services, solution and staff would add to the lower cost of ownership in the long run.

Given the economy and Nehalem-EX features, would it not make sense to take RISC out of your investment?