Yellow Bricks

by Duncan Epping

Archives for 2009

VMware vCenter Chargeback 1.0.1

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VMware has just released a new version of VMware vCenter Chargeback. Below you can find the “what’s new” details from the release notes:

vCenter Chargeback 1.0.1 | 10/29/2009 | Build 204097

Last Document Update: 10/29/2009

What’s New in this Release

vCenter Chargeback 1.0.1 provides the following new features:

  • Support for Windows Authentication
    This release of vCenter Chargeback supports Windows Authentication for SQL Server databases. If you are using SQL Server for the vCenter Chargeback database or for the vCenter Server database, then you can configure the application to use Windows Authentication instead of SQL Authentication.
  • New computing resource and billing policies added
    This release of vCenter Chargeback introduces a new computing resource, vCPU, and two new billing policies, vCPU Count and Memory Size and Fixed Cost and vCPU Count and Memory Size. These policies enable you to calculate cost based on the number of virtual CPUs and the amount of memory allocated to the virtual machines.
  • Resource Summary section lists rolled-up usage data for all entities
    The Resource Summary section of the chargeback reports show the rolled-up usage data for all the entities.
  • Global fixed cost history is retained
    This release of vCenter Chargeback lets you to set different cost values for different time periods on the same global fixed cost. The old values are retained and not overwritten.
  • Ability to undo to the most recent operation on the chargeback hierarchy
    The most recent operation on the chargeback hierarchy can be undone. This undo feature is available for entities that are added or moved in the hierarchy. The undo option is not available for rename and delete operations.
  • Ability to use the vCenter Chargeback APIs
    vCenter Chargeback APIs provide an interface to programmatically use the various features of vCenter Chargeback. As an application developer, you can use these APIs to build chargeback applications or integrate vCenter Chargeback with your internal billing systems and compliance policies. Please do note that the APIs released with this version of vCenter Chargeback are only for a technical preview.

    • 80MB of awesomeness, VMware Player 3

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    While everyone is talking about the new versions of VMware Fusion (Release Notes) and VMware Workstation (Release Notes) I would like to show my appreciation for VMware Player.

    VMware Player is one of the most under-appreciated VMware products in my opinion. Especially now that VMware has released version 3 I expect to see and hear more of VMware Player. Why? Well because it is FREE, and it basically is a slimmed down version of VMware Workstation. With version 3.0 you are not only limited to using pre-build VMs. No, with version 3.0 you can create VMs! Again, it’s free… it’s 80MB of awesomeness.

    Release NotesDownload Link

    Here a couple of new features I think are worth knowing about:

    • Virtual Machine with Easy Install — Create a virtual machine and install any supported guest operating system with Easy Install.
    • New User Interface — Use the new user interface to create virtual machines and edit virtual machine settings.
    • Windows 7 — Create and run Windows 7 32-bit and 64-bit virtual machines using VMware Workstation. VMware Workstation has been enhanced for performance and to take advantage of the new Windows 7 features including Live Thumbnails and Aero Peek.
    • Aero Glass — A new Windows Display Driver Model (WDDM) graphics driver has been developed for Windows Vista and Windows 7 virtual machines. The WDDM driver can display the Windows Aero user interface, OpenGL 1.4, and Shader Model 3.0.
    • 3D Graphics Improvements for Windows XP guests — OpenGL 2.1 and Shader Model 3.0 support is now available for Windows XP virtual machines. The XPDM (SVGAII) graphics driver works with Windows XP, Windows Vista, and Windows 7. However, only Windows XP virtual machines install the XPDM graphics driver by default. To switch graphics drivers in the guest operating system, see How to Switch Between SVGAII and WDDM Drivers.
    • Multiple-Monitor Display — Virtual machines can now take advantage of multiple monitors.
    • Virtual Printing — Print from virtual machines without mapping network printers or installing printer drivers in the virtual machine. With virtual printing enabled in the virtual machine setting, all of the printers installed on the host operating system are available in the guest operating system. This functionality is enabled through a partnership with ThinPrint, Inc.

    DRS Deepdive Blog page

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    Over the last week I received a whole bunch of requests to turn the DRS Deepdive articles in a “blog page” so that they would appear up in the menu. That’s what I just did, so you guys can easily find the info you are looking for. I will also try to add a diagram to the post which visualizes the stages. Probably this week if I can find some spare time.

    Direct Link: http://www.yellow-bricks.com/drs-deepdive/

    DRS Deepdive part II

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    Yesterday I posted the DRS Deepdive. One of the questions still left open was how DRS decides which VM to move to create a balance cluster. After a lot of digging for non-NDA info I found this “procedure” in a VMworld presentation(TA16) amongst some other cool info.

    The following procedure is used to form a set of recommendations to correct the imbalanced cluster:

    While (load imbalance metric > threshold) {
move = GetBestMove();
  If no good migration is found:
    stop;
  Else:
    Add move to the list of recommendations;
    Update cluster to the state after the move is added;
}

    Step by step in plain English:

    While the cluster is imbalanced (Current host load standard deviation > Target host load standard deviation) select a VM to migrate based on specific criteria and simulate a move and recompute the “Current host load standard deviation” and add to the migration recommendation list. If the cluster is still imbalanced(Current host load standard deviation > Target host load standard deviation) repeat procedure.

    Now how does DRS select the best VM to move? DRS uses the following procedure:

    GetBestMove() {
  For each VM v:
    For each host h that is not Source Host:
      If h is lightly loaded compared to Source Host:
      If Cost Benefit and Risk Analysis accepted
      simulate move v to h
      measure new cluster-wide load imbalance metric as g
  Return move v that gives least cluster-wide imbalance g.
}

    Again in plain English:

    For each VM check if a VMotion to each of the hosts which are less utilized than source host would result in a less imbalanced cluster and meets the Cost Benefit and Risk Analysis criteria. Compare the outcome of all tried combinations(VM<->Host) and return the VMotion that results in the least cluster imbalance.

    This should result in a migration which gives the most improvement in terms of cluster balance, in other words: most bang for the buck! This is the reason why usually the larger VMs are moved as they will most likely decrease “Current host load standard deviation” the most. If it’s not enough to balance the cluster within the given threshold the “GetBestMove” gets executed again by the procedure which is used to form a set of recommendations.

    Now the next question would be what does “Cost Benefit” and “Risk Analysis” consist of and why are we doing this?

    First of all we want to avoid a constant stream of VMotions and this will be done by weighing costs vs benefits vs risks. These consists of:

    • Cost benefit
      Cost: CPU reserved during migration on t he target host
      Cost: Memory consumed by shadow VM during VMotion on the target host
      Cost: VM “downtime” during the VMotion
      Benefit: More resources available on source host due to migration
      Benefit: More resources for migrated VM as it moves to a less utilized host
      Benefit: Cluster Balance
    • Risk Analysis
      Stable vs unstable workload of the VM (historic info used)

    Based on these consideration a cost-benefit-risk metric will be calculated and if this has an acceptable value the VM will be consider for migration.

    I will consolidate both post in a single blog page today to make it easier to find!

    DRS Deepdive

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    Last week I mentioned which metrics DRS used for load balancing VMs across a cluster. Of course the obvious question was when the DRS Deepdive would be posted. I must admit I’m not an expert on this topic as like most of you I always took for granted that it worked out of the box. I can’t remember that there ever was the need to troubleshoot DRS related problems, or better said I don’t think I’ve ever seen an issue which was DRS related.

    This article will focus on two primary DRS  functions:

    1. Load balancing VMs due to imbalanced Cluster
    2. VM Placement when booting

    I will not be focusing on Resource Pools at all as I feel that there are already more than enough articles which explain these. The Resource Management Guide also contains a wealth of info on resource pools and this should be your starting place!

    Load Balancing

    First of all VMware DRS evaluates your cluster every 5 minutes. If there’s an imbalance in load it will reorganize your cluster, with the help of VMotion, to create an evenly balanced cluster again. So how does it detect an imbalanced Cluster? First of all let’s start with a screenshot:

    fig 1

    There are three major elements here:

    1. Migration Threshold
    2. Target host load standard deviation
    3. Current host load standard deviation

    Keep in mind that when you change the “Migration Threshold” the value of the “Target host load standard deviation” will also change. In other words the Migration Threshold dictates how much the cluster can be “imbalanced”. There also appears to be a direct relationship between the amount of hosts in a cluster and the “Target host load standard deviation”. However, I haven’t found any reference to support this observation. (Two host cluster with threshold set to three has a THLSD of 0.2, a three host cluster has a THLSD of 0.163.) As said every 5 minutes DRS will calculate the sum of the resource entitlements of all virtual machines on a single host and divides that number by the capacity of the host:

    sum(expected VM loads) / (capacity of host)

    The result of all hosts will then be used to compute an average and the standard deviation. (Which effectively is the “Current host load standard deviation” you see in the screenshot(fig1).) I’m not going to explain what a standard deviation is as it’s explained extensively on Wiki.

    If the environment is imbalanced and the Current host load standard deviation exceeds the value of the “Target host load standard deviation” DRS will either recommend migrations or perform migrations depending on the chosen setting.

    Every migration recommendation will get a priority rating. This priority rating is based on the Current host load standard deviation. The actual algorithm being used to determine this is described in this KB article. I needed to read the article 134 times before I actually understood what they were trying to explain so I will use an example based on the info shown in the screenshot(fig1). Just to make sure it’s absolutely clear, LoadImbalanceMetric is the Current host load standard deviation value and ceil is basically a “round up”. The formula mentioned in the KB article followed by an example based on the screenshot(fig1):

    6 - ceil(LoadImbalanceMetric / 0.1 * sqrt(NumberOfHostsInCluster))
    6 - ceil(0.022 / 0.1 * sqrt(3))

    This would result in a priority level of 5 for the migration recommendation if the cluster was imbalanced.

    The only question left for me is how does DRS decide which VM it will VMotion… If anyone knows, feel free to chip in. I’ve already emailed the developers and when I receive a reply I will add it to this article and create a seperate article about the change so that it stands out.

    VM Placement

    The placement of a VM when being powered on is as you know part of DRS. DRS analyzes the cluster based on the algorithm described in “Load Balancing”. The question of course is for the VM which is being powered on what kind of values does DRS work with? Here’s the catch, DRS assumes that 100% of the provisioned resources for this VM will be used. DRS does not take limits or reservations into account. Just like HA, DRS has got “admission control”. If DRS can’t guarantee the full 100% of the resources provisioned for this VM can be used it will VMotion VMs away so that it can power on this single VM. If however there are not enough resources available it will not power on this VM.

    That’s it for now… Like I said earlier, if you have more indepth details feel free to chip in as this is a grey area for most people.