When I talk with WebSphere CloudBurst users, the topic of custom virtual images comes up frequently. In some cases they simply want to customize a shipped IBM Hypervisor Edition, and in other cases they want to create a completely custom image. Creating a customized version of an IBM Hypervisor Edition is relatively easy since we give you extend & capture in WebSphere CloudBurst. Creating a completely custom image has historically been a bit tougher, mostly owing ot the fact that there was not a standard tool or process for image assembly. I am happy to say that today's publication of the IBM Image Construction and Composition Tool changes all that.
Watch a demo of the IBM Image Construction and Composition Tool
The primary purpose of the Image Construction and Composition Tool is to enable a modular approach to virtual image construction, while taking into account the typical division of responsibilities within an organization. The tool allows the right people within an organization to contribute their specialized knowledge as appropriate to the virtual image creation process. This means OS teams can handle the OS and software teams can handle the appropriate software. A separate image builder can then use both OS and software components to meet the needs of users within the organization. Best of all, the image builder does not need intimate knowledge of how to install or configure any of the components in the image. They simply need to know which OS and software components to use.
When using the Image Construction and Composition Tool, you start by defining the base operating system you wish to use for your images. You can do this by importing an existing virtual image with an OS already installed, providing an ISO for the OS, or pointing to a base OS image on the IBM Cloud. The bottom line is that you have necessary flexibility to start with your certified or ‘golden’ operating system build. Once you have the base OS image defined in the Image Construction and Composition Tool, you can start defining custom software for use in the images you will compose.
In the tool, bundles represent the software you wish to install within a virtual image. The definition of a bundle contains two major parts: Installation and Configuration. The installation component of a bundle tells the Image Construction and Composition Tool how to install your software into the virtual image. You provide a script or set of scripts that install the necessary components into your image, and you direct the tool to call these scripts. These tasks run once during the initial creation of the virtual image, thus allowing you to capture large binaries, long-running installation tasks, or other necessary actions directly into your image.
The configuration section of a bundle defines actions that configure the software installed into the image. Like with the installation tasks, you provide a script or set of scripts for configuration tasks. Unlike installation tasks that run exactly once, configuration scripts become part of the image’s activation framework and as such, run during each image deployment. Using the tool, you can define input parameters for configuration scripts and optionally expose them so that users can provide values for the parameters at image deploy-time. Configuration tasks are important in providing flexibility that allows users to leverage a single virtual image for a number of different deployment scenarios.
Once you have your base OS image and one or more bundles defined in the Image Construction and Composition Tool, you can compose a virtual image. To compose a virtual image, you extend the base OS image and add any number of bundles into the new image. A base OS image plus a set of bundles defines a unique image.
After you define the image you want to construct, you initiate a synchronize action in the Image Construction and Composition Tool. When you start the synchronize action, the tool first creates a virtual machine in either a VMware or IBM Cloud environment (based on how you configured the tool). Next, the installation tasks of each bundle you included in the virtual image run to install the required software. Finally, the tool copies the configuration scripts from each bundle into the virtual machine and adds them to the image’s activation framework. This ensures the automatic invocation of all configuration scripts during subsequent image deployments.
Once the image is in the synchronized state, you can capture it. Capturing the image results in the creation of a virtual image based on the state of the synchronized virtual machine. The tool also automates the generation of metadata that becomes part of the virtual image package. When the capture of the virtual image completes, you can export it from the Image Construction and Composition Tool and deploy it using WebSphere CloudBurst, Tivoli Provisioning Manager, or the IBM Cloud.
I am excited for users to get their hands on the Image Construction and Composition Tool. I believe it represents the first big step in helping users to design and construct more sustainable virtual images. Did I mention it is completely free to download and use? Visit the Image Construction and Composition Tool website for more details and a download link. I look forward to your comments and feedback.
Typically we spend most of the real estate on this blog talking about cloud computing and specifically, IBM Workload Deployer. However, I am hoping that this week you permit me to take a bit of a detour to discuss a very important new announcement. Last week, IBM announced the early availability of the WebSphere Application Server v8.5 Alpha. In all fairness, your response may be 'You guys always have WAS Alphas. Why should I care about this one?' I have two words for you: Liberty Profile.
Based on my own experience in the IBM labs and my conversations with numerous enterprise developers out there, I think I understand many of the needs to create an efficient development environment. Developers need tools and runtimes that are lightweight, easy to install, simple to configure, and fast to recycle or otherwise update. Enhancements in our WebSphere Application Server v8.0 took many of these concerns head on with features such as directory-based install and drastically improved server startup times. The new v8.5 Alpha, and specifically the Liberty Profile, extend this developer focus even further.
The Liberty Profile is a lightweight, fast, and easy to use application runtime that you can download for free by visiting the WASdev community site. The design of the runtime is best described as fit-for-purpose and you configure it by selectively enabling and disabling features based on application need. For example, you may enable the servlet, JPA, and JSP features, or you may decide you only need to enable the servlet feature of the runtime. It is completely up to you! In addition to this innovative new runtime, the WebSphere Application Server v8.5 Alpha also includes free tools for Eclipse. These tools make it simple to create Liberty Profile server instances, start server instances, stop server instances, install applications, and remove applications. In fact, you can do all of this and even download and install the WebSphere Application Server v8.5 Alpha without ever leaving your Eclipse workspace! Check out the demonstration below to see an example of installing and using the new Alpha.
I really hope that you will participate in the new WebSphere Application Server v8.5 Alpha. The setup process that includes both tools and runtime will take just a few minutes of your time, and leaves but a small footprint on your machine (the Liberty Profile of the WAS v8.5 Alpha is only ~50 MB unzipped). In the meantime, you can find more information about the Alpha on the WASdev site or in the new Information Center. Finally, don't forget to join in on the conversation on the WASdev forum!
When one uses IBM Workload Deployer (previously WebSphere CloudBurst) to deploy a virtual system pattern, they benefit from a completely automated deployment process. The automation includes the creation and placement of virtual machines, injection of IP addresses, initiation of internal processes, and invocation of included scripts. Most of these processes are straightforward and require little more than a brief overview. However, the placement of virtual machines stands out, and it's inner workings are the subject of quite a few questions when I discuss the appliance. With that in mind, I thought I would provide a little more information on how the placement algorithm in IBM Workload Deployer works.
The placement subsystem in IBM Workload Deployer considers three primary elements: compute resource, availability, and license optimization. Compute resource availability is the gating factor for placement. That means that IBM Workload Deployer first looks at the available CPU, memory, and storage resource in the collection of hypervisors making up the cloud group(s) you are targeting for deployment. If a particular hypervisor cannot provide enough resource based on the amount you requested for your deployment, then it is automatically taken out of the eligible hosts pool. It is important to note that IBM Workload Deployer will overcommit CPU, and it will overcommit storage if you direct it to do so. It will not overcommit memory because that could severely degrade the performance of the application(s) running in the virtual machines.
After choosing the pool of hypervisors that are capable of hosting the virtual machines in your deployment from a compute resource perspective, the appliance then considers high availability. To better understand this particular placement stage, let's consider an example. Consider you are deploying a pattern based on WebSphere Application Server Hypervisor Edition and it contains two custom node parts. It is conceivable, and in fact likely, that these two custom node parts will host members of the same cluster, and thus the two nodes will support the same applications. As such, IBM Workload Deployer will attempt to place the two custom nodes on different physical machines in order to prevent a single point of failure. Of course, this depends on having two hypervisors with enough resource (CPU, memory, storage) to host the virtual machines, but the appliance makes that decision in the first placement stage.
After considering compute resource and high availability, IBM Workload Deployer moves to the last stage of placement: license optimization. In this stage, the placement subsystem attempts to place the virtual machines on hypervisors in a way that minimizes the licensing cost to you. The appliance can do this because it is aware of IBM virtualization licensing rules and takes those into account during this stage (if you aren't familiar with virtualization licensing rules and you are curious, ask you're sales representative to explain some time). During this stage, it will not violate any resource overcommit directives or rules in place, nor will it compromise system availability, but it will seek to minimize costs within these parameters.
At this point, I should make something clear that may already have occurred to you. You can override most of these placement rules by creating a cloud group containing only one hypervisor. In this case, IBM Workload Deployer will put all virtual machines on the single hypervisor until it runs out of compute resource (memory is likely to be the constraining factor). I would not suggest that you do this unless you have a good reason or you are in a simple pilot phase, but I do like to point out the art of the possible!
While not incredibly deep from a technical perspective, I do hope that this provided a few helpful details on what goes on during the placement stages of deployment. If you have any questions, do let me know.
As a final preview of this week's building block sessions in the Enabling cloud computing with WebSphere campaign, I caught up with WebSphere DataPower architect Tim Smith. Tim is delivering a podcast that introduces and explains the new Application Optimization capabilities in the WebSphere DataPower line of products. Here is what Tim had to say:
Me: I speak with quite a few customers about the WebSphere CloudBurst Appliance, and for once I'm happy to be the one asking this question. Why do we deliver WebSphere DataPower in the appliance form factor?
Tim: DataPower has become a dominant player in the DMZ and in the ESB. Much of the reason is that this is a purpose built hardware appliance. There are many things that our customers like about this appliance package. First, it has security as part of its DNA. The basis for securing connections, applies throughout the network whether it is in a DMZ or in an ESB. The physical box provides tamper resistant protection. Another reason is availability -- there are no spinning media, dual power supplies, and a focus on fail over support.
In both the DMZ and the ESB, there has been a proliferation of products. The main reason for the proliferation is that customers want to remove as many decisions from the general purpose server as possible, and let servers do what they do best, process application requests. The devices that have been proliferating make more decisions on the request. They do deep packet processing and routing. They also may transform the request into an entirely different request. So, there are an abundance of "pre-processing" decisions and operations made. With DataPower, many functions are integrated into the single hardware platform, giving you a smaller box count. No need to purchase and maintain several platforms, their OS and software versions, compatibility lists, etc. With a single hardware box that does so many things, we can greatly reduce the total cost of ownership for our users.
The DataPower appliance is a blend of Hardware and firmware that is well provisioned with hardware assists that help compile, parse, and assist in many of the intensive packet processing capabilities. To summarize, you get an extremely flexible and adaptable product that reduces total cost while increasing performance.
Me: A theme that comes up in cloud computing over and over is consolidation. Can you speak to the consolidation offered by WebSphere DataPower appliances with respect to the self-balancing capabilities?
Tim: Yes. My answer to the prior question was a long-winded way of describing DataPower's ability to consolidate many features into a single platform. Self-balancing is an example. As DataPower became more popular, larger installations required multiple DataPower appliances in a tier of platforms. A common architecture was to place a load balancer or IP sprayer in front of the tier to distribute the traffic evenly among the tier of DataPower appliances. An IP sprayer is an example of another platform that needs to be added to the environment. It is another box that must be purchased, managed, and maintained. Self-balancing is a feature that was added to DataPower to eliminate the need for an IP sprayer. The way it works is that one of the DataPower appliances in the tier owns the Virtual IP (VIP) Address. It receives all of the traffic, and then distributes it to each of the other DataPower appliances in the tier. If the DataPower appliance that owns the VIP address goes down, one of the others is elected and it takes over. The result is one less product required to support the same level of functionality.
Me: For much of the past, cloud computing mostly focused on virtualization and management of resources at the raw compute level (servers, storage, networking, etc.). While there is definitely ongoing focus here, we start to see it moving up the stack towards applications, and part of that effort includes more evolved application load distribution. With that in mind, how can WebSphere DataPower help users more effectively distribute requests to their applications?
Tim: If a front end appliance or gateway device can dynamically learn information about its environment, specifically the back end, it will be able to make better decisions on how and where to route the request. This is one of the tasks that the Application Optimization feature addresses. Information from the back end can of course be manually configured, but the real value in cloud computing is dynamically adapting when new server resources are brought on line or are taken off line. In the 3.8.0 release, we implemented something called Intelligent Load Distribution (ILD). Intelligent load distribution focuses on continually learning the topology of a back end, updating DataPower's load balancers with that information, and distributing the load based on the updates. In addition to the topology, ILD learns the weights associated with each server. These weights can continually and automatically change as traffic patterns change. The result is load balancing to the back end that sends the optimal amount of load to each server.
Another traffic distribution aspect incorporated into ILD is session affinity. When a server application needs to receive every request from a given client, session affinity is used to route the requests to the same server. In some sense, session affinity overrides the load balancing algorithm. The session affinity support works with any type of back end server, but with a WebSphere back end, all session affinity information is automatically configured.
Me: Continuing on the theme of application intelligence, what is this new Application Routing option in WebSphere DataPower?
Tim: ILD focused on learning the topology of the network and making better decisions based on an ever changing cloud topology. Application Routing does something similar by learning which applications are running on each server. Once a request is handed to DataPower's load balancer, the request is classified as to the application that it is targeted for. Then the request is load balanced amongst the servers that are running that application. The information to perform application routing is dynamically learned and changes as applications are added or removed.
WebSphere has invested substantially in managing the life cycle of an application. Changing from one edition of an application to the next sounds like an easy task, but it can be very difficult to perform this type of maintenance on a production environment. The DataPower appliance supports life cycle management by working with the WebSphere back end to provide group and atomic edition rollout. The rollout feature allows traffic to be gracefully diverted from servers that are being taken offline and reloaded with the new application edition. This rollout can be done while leaving the other applications on the server unaffected. This support makes edition rollout a very simple task for the system administrator.
Next up on our sneak preview of the building block sessions for the Enabling cloud computing with WebSphere campaign is the Dynamic Infrastructure Services block. One portion of that block is a discussion about some of the technical capabilities of WebSphere Virtual Enterprise given by Nitin Gaur. Nitin is a Consulting IT Specialist within WebSphere, and an all-around WebSphere guru. I caught up with him to ask a few questions about his upcoming podcast.
Me: When people think cloud computing, one of the core concepts is 'on demand'. They want just enough resource at just the right time. In that sense, can you tell me a little about the On-Demand Router (ODR) in WebSphere Virtual Enterprise (WVE)? What is it and what core functions does it provide?
Nitin: So, first allow me to take a step back. In my view, cloud computing is a new consumption and delivery model nudged by consumer demand and continual growth in internet services. I classify any Cloud computing platform exhibits the following 6 key characteristics:
Standards based delivery
Usage based equitable chargeback
I thus, deliberately use the term platform in the context of a cloud computing environment that facilitates flexibility, robustness and agility, as a systemic approach in providing a stage to hosting applications without the concern for availability or provisioning of underlying resources. Since hardware and software virtualization do offer significant cost and resource management advantages, it is not rare to see virtualized platforms as core building blocks of any cloud platform. Such virtualization technologies provide an elastic infrastructure service. In this respect, WVE provides application server virtualization, which enables an elastic business-policy-driven application infrastructure.
Now back to the On-Demand Router. The ODR is the autonomic engine that drives the activity enabling the elastic infrastructure discussed above. The ODR operates in a highly dynamic WVE environment, so it is imperative for the ODR to be aware of any changes in the environment such as newly deployed applications, the addition of new application servers, and any planned or unplanned server outages. It achieves this awareness by continuously interacting with WVE's fluid and dynamic feedback mechanism.
Me: Autonomic capabilities seem to be a core part of WebSphere Virtual Enterprise. To that end, can you tell us a little about the autonomic capabilities provided by dynamic clusters in WVE?
Nitin: Dynamic application placement is a defining capability of WVE that directly contributes to WVE's ability to provide a dynamic, virtualized, and goal-oriented environment for workload management and continuous availability. The dynamic application management capability maximizes the efficient use of hardware resources by allocating resources appropriately per application based on fluctuating demands in the enterprise infrastructure. It determines which servers to stop and start in a dynamic server cluster in order to meet current demand for applications, and it does this in the context of a set of administrator-defined policies that uphold the enterprise’s service level agreements (SLAs) for its application infrastructure. The dynamic application placement framework must balance resource availability against health policies, service policies, and the importance levels assigned to applications.
Dynamic server clusters are key to WVE’s ability to dynamically adjust the application environment according to server load, and they provide the basis for a virtualized server runtime environment. The big difference between a dynamic cluster in WVE and a static cluster in WebSphere Application Server is that dynamic clusters grow and shrink as needed to meet current demand by starting and stopping members of the cluster. Although dynamic clusters and static clusters can co-exist in a cell, dynamic application placement can only work with dynamic clusters. To prevent unchecked growth, each dynamic cluster has a mechanism that you use to define a boundary for that cluster’s growth. The boundary is both quantitative (based on criteria that define the minimum and maximum number of application servers that can run in the cluster simultaneously) and locational (based on criteria that confine the growth of the dynamic cluster to a defined set of nodes).
Me: I know you have been around the country, and for that matter globe, helping our users to adopt and implement WebSphere Virtual Enterprise. Tell us about one of your favorite customer stories.
Nitin: So I would cite an example of one of the leaders in the entertainment Industry (and my favorite customer), let's call them Company X (since I cannot cite the name). The core of the company's application infrastructure system is the Sales App Infrastructure (SAI) consisting of more than 10 enterprise applications. To keep up with demand, Company X was required to procure more hardware and software to support the core systems. This strategy resulted in a large infrastructure footprint with low hardware utilization. The increase in hardware footprint became difficult to manage and required additional resources. The large footprint of the company's deployment put them in reaction mode rather than a posture of proactive monitoring. Some application servers rendered themselves unavailable and required the team to restart them every 24 hours. From a cost standpoint, it costs the company the same amount of money to request a virtual platform as it would to purchase a new physical server. This led to significantly under utilized hardware throughout the enterprise. WVE was brought in to Company X to help better manage their WebSphere Application Server footprint. Dynamic clusters, application health policies, and application editioning features helped the company to better utilize hardware, reduce hardware expenditures, increase visibility into their applications, and improve availability of their applications.
In addition to helping with the existing environment, WVE helped Company X to roll out a new project with applications that required continuous availability to worldwide users. The team made use of policy-based workload management to ensure performance and availability levels of these new applications met their business needs. In addition, the company was able to reduce the amount of WebSphere Application Server licenses and physical servers required for this new deployment. In sum, WebSphere Virtual Enterprise saves the company significant time, money, and management effort.
Yesterday, we kicked off a WebSphere in the Clouds campaign designed to connect you with IBMers that can help you to leverage WebSphere solutions to build clouds. The campaign consists of webcasts, podcasts, live Q&A sessions, and online JAMs. You can listen to replays and sign up for upcoming events by visiting the Global WebSphere Community website.
Next week, the campaign delivers a series of podcasts that discuss the WebSphere technologies that form the building blocks of clouds. These podcasts will discuss both the business and technical aspects of these solutions, and they will cover topics like application infrastructure in the cloud, policy-based workload management using application virtualization, hybrid cloud integration, and more. Over the past few days, I had the opportunity to catch up with the various presenters of these podcasts to ask them a few questions about their solutions. These interviews provide a nice sneak peak at what is coming in the podcasts, and I will be posting them here in the coming days.
To kick things off, I'm posting a video interview with Marc Haberkorn. Marc is the WebSphere Product Manager for WebSphere CloudBurst, WebSphere Application Server Hypervisor Edition, and WebSphere Virtual Enterprise. My colleague, Ryan Boyles, caught up with Marc and got his thoughts on how these solutions enable virtualization and automation for your cloud environments. Enjoy!
When it comes to building and using WebSphere CloudBurst patterns, people always ask me if I have any best practices. It turns out, I do. In fact, I have a singular piece of advice that wraps it all up: Build WebSphere CloudBurst patterns in a way such that once deployed, there is no after-the-fact, manual configuration for the running environment. That means, build the pattern so that it not only contains all the nodes necessary for your application environment, but it also contains all the configuration necessary for the environment.
Put like this, most everyone I talk to agrees with me. However, they quickly recognize that, absent this really cool integration with Rational Automation Framework for WebSphere, this means they will be writing scripts for many configuration actions and including them in patterns in the form of script packages. For users not familiar with configuration scripting for our WebSphere products, this can be a daunting proposition. But... it shouldn't be!
Recently, I put together a short presentation that lays out an iterative approach for developing script packages for WebSphere CloudBurst. Specifically, the presentation focuses on developing configuration script packages for the WebSphere Application Server (though the general concepts apply to all Hypervisor Edition products equally). I believe this method is useful for anyone, from novice users to WebSphere scripting gurus. The basic process goes something like this:
Identify: Identify the target WebSphere Application Server topology and configuration for your application environment.
Deploy: Build a WebSphere CloudBurst pattern that matches your desired topology and deploy it to your cloud.
Develop and Test: Develop and test your configuration script. Not a WebSphere Application Server scripting ninja? No worries. Use the Command Assistance feature in the WebSphere Application Server v7 administration console. This feature shows you the wsadmin commands that match the actions you manually take in the console. This affords a lower barrier of entry for those not familiar with wsadmin.
Package: Package up the resulting scripts into a script package along with metadata that describes the package.
Modify and redeploy: Load the new script package into your appliance, add it to your pattern, and then redeploy. Upon deployment completion, verify the scripts produce the desired result.
The presentation provides detail on the above steps and walks through an example scenario for this process. I am embedding it below, and I hope it proves useful. As always, feel free to send in any questions or comments.
May is almost here and that means that IBM IMPACT is right around the corner. Just like years past, IMPACT 2010 will be a great chance to get valuable education and insight into IBM WebSphere software and software from across the IBM software family. If you want to hear how IBM software is leading the march toward a smarter planet, register now.
IMPACT 2010 will be a great chance to hear the WebSphere cloud computing story. There will be multiple sessions on the WebSphere CloudBurst Appliance. These include customer-led sessions, internal adoption stories, overviews, and much more. I'll be there running a hands-on lab and delivering a session that discusses integration between WebSphere CloudBurst and IBM Rational tools. Of course, there is more to WebSphere and cloud computing than WebSphere CloudBurst. We have several other sessions that will detail all of IBM WebSphere's work in the cloud.
If you are interested, I put together a short video discussing some of the sessions on tap for WebSphere and cloud computing at IMPACT 2010. I'd also encourage you to check out the social media site for IBM IMPACT 2010. On that site, you will find tweets, videos, and blogs about the conference. Don't forget to sign up, and I hope to see you in Las Vegas!
-- Dustin Amrhein
If you follow this blog often, you know that from time to time I like to post frequently asked questions. Well, it's been a while since I have done that, and since then I have added some new questions to my list -- along with some regulars. Take a look below, and if I don't answer your question feel free to leave a comment!
Can IBM Workload Deployer deploy software that is not IBM software? Yes. You can use one of the included images as a springboard and customize them with your own software via extend and capture. Additionally, you can use the IBM Image Construction and Composition Tool (I'm getting ahead of myself here) to create your own custom images from the ground up and use those within IBM Workload Deployer.
Can I use VMotion for the systems I deploy with IBM Workload Deployer? Yes. IBM Workload Deployer has tolerated the use of VMotion since the WebSphere CloudBurst days (see the Additional Considerations section on this page for more information). IBM Workload Deployer v3 introduced the notion of virtual machine mobility initiated directly from the appliance. This capability takes advantage of VMotion in the case of VMware-based cloud environments.
Can IBM Workload Deployer deploy just a base operating system? Yes. IBM Workload Deployer v3 introduced a base operating system image that contains 64-bit Red Hat Enterprise Linux. Internally, IBM Workload Deployer uses this as the foundation on top of which virtual application patterns are deployed. You can use it to deploy virtual machines containing just the base OS, or you can customize it to deploy software of your choosing. (As an aside, IBM Workload Deployer v3.1 will include a base operating system image for AIX)
Can I automate the process of calling/using IBM Workload Deployer? Yes. IBM Workload Deployer is built to fit a specific need -- creating and managing a cloud of middleware and middleware-based workloads. In that light, it would be a shortcoming if IBM Workload Deployer did not to fit well into more holistic or enterprise-wide cloud management systems. The REST API and CLI allow you to automate the use of IBM Workload Deployer, thereby allowing it to be mashed up into other processes.
Can I group two appliances together for high availability? Yes. IBM Workload Deployer v3.1 introduces the ability to configure appliances in a master/slave setup. You can connect two appliances, allow them to share a floating IP address, and be confident that data is continuously replicated between the two. If one appliance fails, the other appliance picks up the floating IP ensuring continuous service.
Are images created using the Image Construction and Composition Tool supported for use within IBM Workload Deployer? Yes. Part of the new IBM Workload Deployer 3.1 announcement was a statement of support for using images created by the Image Construction and Composition Tool as a component of your virtual system patterns. This is a very important enhancement as it allows you to extend the set of content deployed by IBM Workload Deployer while being sure that you are operating within the boundaries of intended use.
Can I use IBM Workload Deployer to provision to public clouds? No... and yes. If you install an IBM Workload Deployer appliance in your datacenter, you cannot use it to deploy to a public cloud environment. However, you may have recently heard about the IBM SmartCloud Application Services portfolio. IBM has announced that the pattern-based provisioning that one gets with IBM Workload Deployer will also be available as part of this portfolio. This means that you will be able to build and deploy patterns using a service hosted on the IBM SmartCloud. Further, your deployed systems will run on the IBM SmartCloud. Check out this demo for more information.
** IBM Workload Deployer 3.1 firmware is available on 11/18.
For those of you basically familiar with IBM Workload Deployer, you are likely aware that the appliance has many different capabilities. On the surface it is a cloud management device for middleware and middleware applications. Of course, there are quite a few details that are important to understanding the functionality provided, and I spend quite a bit of my time talking with various users and potential users about these details. One thing I have noticed that can become an obstacle in having effective communication regarding IBM Workload Deployer is the lack of a commonly understood language. I sometimes find that me and the user are simply using different terminology to describe the same thing. As you can imagine, this just serves to create confusion, and neither party gets the most out of the conversation.
In order to combat this communication gap, I thought I would put together a simple presentation that introduces and defines IBM Workload Deployer terminology. Check it out below (you can also download it here):
While the presentation does not dive deep into the terms it introduces, it does provide a basic definition and illustrative example of each. My hope is that this fosters an understanding of some of the basic concepts in IBM Workload Deployer, and ultimately pushes us towards a common vernacular. Please let me know what you think!
A couple of weeks ago, I dropped by the Intel Developer Forum to present a session and listen in on a few others. As always in these types of shows, I learned quite a bit. Most strikingly though, I was reminded of something that is probably quite obvious to many of you: Consumer interest in cloud computing will not be letting up any time soon.
Based on this, and some of the other things I heard at the show, I decided to catch up with fellow IBMer Marc Haberkorn. Marc is an IBM Product Manager and is responsible for IBM Workload Deployer amongst other things. I asked him about IBM Workload Deployer, the competition, and cloud in general. Check out what Marc had to say below:
Me:IBM Workload Deployer is one among many of a growing wave of cloud management solutions. How do you differentiate the focus and business value of it versus the myriad of other solutions out there?
Marc: To sum it up, we offer a combination of depth and breadth. IWD delivers both workload aware management and general purpose management. Workload aware management differentiates IWD from its competition, as it can deliver more value for the set of products for which it has context. There is a set of actions that workload aware management tools can do that is normally left to the user by general purpose management tools. This list includes configuring a middleware server to know its hostname/IP address, configuring multiple middleware servers to know of one another, arranging clusters, applying maintenance, and handling elasticity. By handling more of these activities in the automated flow, there are fewer chances for manual errors and inconsistencies to enter a managed environment.
That said, without infinite resource or time, it’s impossible to deliver this context-aware management for everything under the sun. As such, in order to allow IWD to deliver differentiated value AND allow it to handle a customer's entire environment, we offer a mix of workload-aware management and general purpose management.
Me:VMware is a good example of a company active in the cloud space, and they seem to keep a consistent pace of new product delivery. What do you think of their product development focus?
Marc: I think VMware has built a very compelling set of capability in the virtualization space. I think the main difference between VMware's suite and IBM Workload Deployer is the perspective from which the environments are managed. VMware puts the administrator in the position of thinking about infrastructure from the ground up. The administrator is thinking about virtual images, hypervisors, and scripts. In IBM Workload Deployer, we think about things from the perspective of the app, because that's ultimately what the business cares about. By providing a declarative model through which an application can be instantiated and managed, we feel we deliver a deeper value proposition to clients, through workload-aware management.
Me:The 'one tool to do it all' approach is a popular, if not hard to achieve goal. What is your advice to users when it comes to choosing between breadth and depth for cloud management solutions?
Marc: The advantages of a "one tool to do it all" are many: less integration, more uniformity, less complexity. As such, customers will always prefer a single tool when possible. This is why IBM Workload Deployer has focused on not only providing differentiated, deeper value for common use cases but also providing a way to handle the "everything else." As such, my advice to users is not to choose between breadth and depth - use IBM Workload Deployer which offers both.
Me:To close, I'm curious to know where you think we are heading in the cloud market. What do you think users will be most readily adopting over the next one to two years? Where does the cloud industry need the most innovation?
Marc: I think most users are currently looking at the broad picture of cloud computing, and have been adopting primarily in the private cloud realm. There are several reasons for this. One reason is that many customers have a large set of hardware resources which amount to sunk cost that needs to be leveraged. Another reason is around data security concerns in off-premises clouds, and still another reason is around the human factor of comfort, which has taken time to develop around off-premise cloud models. However, businesses have become increasingly comfortable with various sources of outsourcing in recent years, especially in mission critical areas involving very sensitive data. Just look at IBM's Strategic Outsourcing business, which handles entire IT operations for many large businesses. I think that trend will (and really, has already begun to) continue in the area of cloud computing, and will lead to more public and ultimately hybrid cloud computing adoption. In order to get to hybrid cloud computing, I see much of the focus and innovation being associated with data security, workload portability (across private and public, in a seamless fashion), and license transferability between private and public. When this space reaches fruition, clients will be able to enjoy true elastic economics in a computing model that allows a mixture of owning and renting compute resources and software licenses.
Customization capabilities have been very important to the design of IBM Workload Deployer going back to the beginning with WebSphere CloudBurst. Having the ability to quickly spin up environments in a cloud really does little good if those environments are not customized according to your needs. If you look at the virtual system pattern capability, it is why we always had the notion of custom images, custom patterns, and custom scripts. We give you a strong foundation, and you tweak it here and there to create what you want.
Customization is not a concept unique to virtual system patterns. The virtual application model in IBM Workload Deployer supports many different mechanisms for you to tailor your cloud-based environments. You can start with the virtual application pattern types that we ship and use any components in those patterns to build a custom environment. The patterns you build can include your own configuration (within the set of configurable parameters) and include policies that you need for your environment. In looking at just the IBM Workload Deployer Pattern for Web Applications and the IBM Workload Deployer Pattern for Databases, there are quite a number of scenarios you can support with your cloud. However, what happens when you want to go a little further and color outside the lines of what we provide?
At some point you may have heard or read that the entire virtual application pattern model resides on a pluggable architecture. In effect, this means that everything about a virtual application pattern type, from the elements that show up when building a pattern to the management interface you interact with after deployment, is customizable. The fundamental unit of customization for a virtual application pattern type is a plugin. Plugins provide the know-how in terms of installing, configuring, integrating, and managing the application types supported by a given pattern. Plugins also provide metadata that control what users see as they build and manage these patterns. In short, plugins are the source of truth for virtual application patterns!
If you looked in IBM Workload Deployer, you would find the collection of plugins that support the virtual application pattern types shipped with the offering. While that is interesting, you should also know that you can supply your own plugins. That's right. You can develop a plugin, and load it directly into the appliance. This allows you to do two very important things. First, you can extend the virtual application pattern types that come with IBM Workload Deployer with any kind of functionality you deem important. This may be additional monitoring, integration with external systems, or any number of other extensions. Second, you can create new virtual application pattern types that support your desired workloads. You can support the workloads with the software of your choosing so long as you can supply the necessary know-how in your plugins. In either case, you contribute the plugin, and your customized components become first class members of the IBM Workload Deployer landscape.
Okay, so I admit that this is not necessarily news. We have supported user-contributed plugins since the release of IBM Workload Deployer. However, there is something new that significantly lowers the barrier to entry in the custom plugin game. Early last week, IBM announced the IBM Workload Plugin Development Kit. This kit provides a set of tools and samples designed to make the construction and packaging of custom plugins a simple process. In my opinion, this reiterates our commitment to an extensible, application-centric cloud approach, and it represents a huge step forward in the industry as a whole. Be sure to check this out, and don't be shy with the comments and feedback!
As Joe mentioned in his last post, virtual application patterns are all the rage in IBM Workload Deployer. The high degree of abstraction provided by these patterns means users can remove tedious, time consuming tasks like middleware installation, configuration, and integration from their field of view. As a consequence, users can build and deploy application environments in unprecedented time, thus freeing up more time to focus on the actual application.
This is obviously important because building and deploying application environments are crucial, traditionally time consuming activities. However, what happens after you build and deploy the application? You manage it, that's what! Joe brought up the fact that IBM Workload Deployer makes this easier too by delivering an integrated management portal through which you can manage and monitor your application environments. Now, this probably already sounds valuable, but what really puts it over the top is the management portal exposes an interface that is workload aware. But, what does that mean?
To get an idea of what that means, consider the case that you use the shipped virtual application pattern to build a simple application environment with a web application and database. You deploy it with IBM Workload Deployer, and your application is up and ready. Now you want to start checking things out. You start by opening the management portal directly from the appliance, and you see both the application and database components listed in the view:
After you looked at basic machine statistics such as network activity and memory usage, you could move on to a more workload-centric view. For instance, you could examine statistics particular to a web application such as request counts and service response times:
You may also decide that you want to alter certain aspects of your deployed environment. As an example, you could update your deployed application or change certain configuration data in the deployed environment:
It is important to note that you have a management interface for each of the components in your environment. That means that from the same management interface, you can manage and monitor the database you deployed as part of your environment. For example, at different intervals, you may want to backup your database. You can do this directly from the management portal provided by IBM Workload Deployer:
Lest you think that you can only manage and monitor, this unique management interface is also a one stop shop for all of your troubleshooting needs. From the centralized portal, you can view log and trace data for each component:
Virtual application patterns are an attempt to encapsulate each phase of your application's lifecycle, from creation to deployment to management. In this regard, I hope the above provides a taste of some of the management capabilities provided by virtual application patterns. It truly is the tip of the iceberg!
In a post not long ago, I mentioned new enhancements to virtual system patterns in IBM Workload Deployer. A prominent part of those enhancements were updates to pattern construction that allow you to order virtual machine startup, order script package invocation, and include add-ons that provide system level configuration options. Recently I uploaded a demonstration to YouTube that highlights some of these new capabilities. Specifically, this provides a brief look at ordering and add-on enhancements.
I hope you take a look, and even more importantly, I hope to see some feedback. If you have something you would like to see captured in a demo, let me know and I'll work it to the top of a long and continually growing list!