I point this out about script packages because recently I put one together that is not a WebSphere Application Server administration task, but does provide configuration logic common to many WAS deployments. Specifically, I put together a script package that configures an IBM HTTP Server to be a reverse proxy server. This of course, allows clients to send requests to the IBM HTTP Server and have those requests pass through to a specified back-end destination (i.e. a service hosted on WebSphere Application Server) based on URI paths.
The script package is not all that different from many of the ones I put together. It contains a shell script (which provides configuration and orchestration logic) as well as a cbscript.json file that defines the script package's characteristics when I upload it into WebSphere CloudBurst. The notable difference in this script package is that I include a Perl script that modifies the IBM HTTP Server configuration file. This just reiterates the point that you are not limited to only wsadmin and shell scripts within your script packages.
The workings of the script package are quite straightforward. It starts with a call to the shell script that modifies the IBM HTTP Server's configuration file to ensure the loading of a couple proxy modules:
sed -i s/"#LoadModule proxy_module modules\/mod_proxy.so"/"LoadModule proxy_module modules\/mod_proxy.so"/g $HTTP_CONF
sed -i s/"#LoadModule proxy_http_module modules\/mod_proxy_http.so"/"LoadModule proxy_http_module modules\/mod_proxy_http.so"/g $HTTP_CONF
As you can see, the createProxy.pl script accepts a single argument. This argument represents the reverse proxy configuration information provided by the user during deployment. The Perl script parses the single argument and creates the appropriate proxy directives in the IBM HTTP Server's configuration file:
After the invocation of the script above, control returns to the shell script. The shell script restarts the IBM HTTP Server so that the configuration changes take place. The result is an up and running IBM HTTP Server acting as a reverse proxy based on information supplied during deployment. The listings here do not show the full script package, but I hope to have it up on our WebSphere CloudBurst Samples Gallery soon.
If the script above provides some configuration logic you can use, that is good. However, my main point for bringing it up here is to point out that WebSphere CloudBurst script packages can be more than shell and wsadmin scripts that perform WebSphere Application Server configuration tasks. You can use them to do any sort of scripted activity that is essential to your application middleware deployment process. Happy scripting!
Many enterprise IT decision makers are probably currently, or will be shortly, contemplating some type of cloud computing solution that promises to deliver benefits to their operation. After all, cloud computing solutions, when utilized prudently, are hard to resist. As these decision makers prepare to weigh the pros and cons of such solutions, there is one consideration that is perhaps more important than all others: Will this solution enable elasticity among my services and applications?
Hopefully the answer to the above question is a confident 'Yes'. A lot of discussion is given to providing virtualized, dynamically scaled resources such as servers, processors, operating systems, etc. and rightfully so. By optimizing the usage and consumption of these infrastructure resources, IT operations can be significantly enhanced. However, these resources are often times just a mean to an end, that end being service delivery. IT provides services and applications to end-users that are critical in terms of revenue generation or optimal business activity. These are the resources that most need elastic capabilites to ensure that end-users are continually provided responsive service. Cloud computing solutions need to address this capability by providing the means to package services in manageable units and deliver the ability to govern the scale of these units in an autonomic fashion.
Note, that in the question above I used the word enable. This was deliberate since it is hard to comprehend how any cloud computing solution could provide "out-of-the-box" service elasticity. The implementation of a SOA architecture becomes a necessary partner to achieving true service elasticity. Services must be developed in such a way that they are loosely coupled from other services and required components such as databases. Otherwise, the ability of one service to dynamically scale may be implicitly connected to another service's ability to achieve such elasticity. In this type of intertwined architecture, maximum elasticity will never be achieved.
What do you think about the current cloud landscape? Is there enough focus on service elasticity, and is service elasticity even the most valuable aspect of cloud computing? Leave a comment below, or reply to us on Twitter @WebSphereClouds.
In the previous post I spoke about how a Virtual Application feature introduced in Workload Deployer v3.1 actually had benefits for Virtual System patterns as well. In that case I was talking about the ability to deploy Virtual Applications running on AIX to PowerVM hypervisors and how this had hidden benefits for Virtual Systems as well. This is a great example of how an enhancement to Virtual Applications can sometimes benefit Virtual Systems. However, this is not the only instance where the two pattern types intersect.
Several other new or enhanced features that are primarily for Virtual Applications are also being extended to benefit and improve Virtual Systems ... and vice-versa. One such area of improvement involves Shared Service in v3.1. These services were introduced in v3.0 specifically for the benefit of Virtual Applications. However, several enhancements have extended these capabilities to Virtual Systems and likewise, some functionality that was previously only available to Virtual Systems has been extended to Virtual Applications in the form of Shared Services.
As you may already know, Shared Services were first introduced in v3.0 and are just what the name implies; services that are deployed by a cloud administrator and used by multiple virtual application deployments. Let's start by taking a look at the shared services available under Cloud -> Shared Services in v3.1. You will notice that there are now more shared services listed than there were in v3.0.
In addition to the familiar Caching Service and ELB Proxy Service (formerly Proxy Service) there are now additional entries for an External Caching Service and an External Application Monitoring Service. For simplicity let's just start from the top and go down the list, discussing the function of each service, what is new/improved for v3.1 with regard to virtual applications, and when applicable how this service can be used by virtual systems.
The Caching Service was introduced in v3.0. Its primary purpose is to cache HTTP session data using a highly scalable and fast in-memory cache. This is the same core technology that is included in our WebSphere eXtreme Scale and DataPower XC10 Caching appliance. To make use of this service all you need to do is deploy an instance of the Caching Service with the configuration parameters of your choice into a cloud group where you want to leverage that service. As you create virtual application patterns you simply select the Enable session caching check-box when you add a scaling policy. When this pattern is deployed it will be automatically configured to leverage the Caching Service for session persistence. It's as simple as that.
Several new features were introduced in v3.1 for the Caching Service. First, the Caching Service can now be launched with parameters to define the behavior for automatic scaling to meet the ever changing demands of your applications. Once set, Workload Deployer will manage this service to ensure sufficient capacity based upon your requirements, adding or removing containers. Second, and this is significant for Virtual System patterns, the caching service has been enhanced to add new operations to support listing, creating, and deleting various types of object grids. You can then use the WebSphere eXtreme Scale ObjectGrid APIs to persist and manage content in the grid from your application code from Virtual System deployments. This saves you the trouble of creating and configuring your own caching service for these purposes outside of the cloud and permits sharing of the service you have already configured - a nice savings.
Caching Service (External)
The External Caching Service is one of the new additions for v3.1. Let's say that you already have configured a caching solution for your enterprise using the DataPower XC10 appliance or a collective of appliances. It would be nice if you could leverage this same solution instead of launching yet another caching solution within your private cloud. Leveraging your existing solution would consolidate your caching needs and preserve the cloud resources for other purposes. With this new external caching service you can do just that. It provides you the ability to leverage an external caching solution for both your Virtual Application session persistence needs as well as your Virtual System and even non-cloud caching needs. Just point an instance of this external caching service at your DataPower XC10 caching solution and all of the HTTP session persistence needed by your virtual applications in the same cloud group will make use of the external caching service. You can also point multiple instances of the external caching service in multiple cloud groups to share the same XC10 appliance or collective.
Monitoring Application (External)
With the External Monitoring Application service you can deploy an External Application Monitoring service reference within a cloud group to point at a Tivoli Enterprise Monitoring Server installation outside of the cloud. The TEMS server must be at version 6.2.2 Fix Pack 5 or later. Once created, the Unix or Linux OS monitoring agents and the Workload monitoring agent that is provided for virtual application workloads will be automatically connected to the defined instance of the Tivoli server using the supplied primary and fail-over Tivoli Enterprise Management server, protocol, and port. This is especially useful if you want to consolidate all of your monitoring to a common console. As with the External Caching Solution, this enhancement also extends the integration capabilities of Virtual Application Patterns beyond the scope of your private cloud and allows you to consolidate and leverage investments you have already made.
ELB Proxy Service
The Proxy Service was first introduced in v3.0 and renamed to the ELB Proxy Service in v3.1 for clarity. As the name implies, its primary purpose is to provide routing and load balancing to multiple deployed web applications. As with the caching service, you deploy this service based upon your requirements for load and availability within a cloud group. When defining virtual application patterns to leverage this service you simply add a routing policy and define your virtual host name. When the virtual application pattern instance is deployed to the cloud group the necessary configuration will performed to add the virtual host name and configure your application environment to use the ELB Proxy Service. New in v3.1 is the capability to scale the ELB Proxy Service itself to meet the changing demands of your application mix.
One other item that I should point out (and to which I've already alluded) is that you can now deploy multiple instances of each of the shared services - one per cloud group. Shared services can also now be deployed using environment profiles. This was not previously the case in v3.0 where each service was a singleton for the appliance. Allowing multiple instances of shared services gives you the flexibility to configure the sharing of your services as necessary for your particular environment.
I hope this post has provided a useful overview of the value of shared services and the new capabilities introduced in v3.1. I also hope that you can see how these services make it easier to implement your solutions for both virtual applications and virtual systems within a private cloud environment and shed a little light on how we are continuing to improve IBM Workload Deployer. As always, these improvements are driven by the feedback we receive from you so please let us know what you think!
If you are going to install and use WebSphere CloudBurst in your own environment, it is very likely that you would want at least two appliances. Perhaps you want to have a standby appliance in case of a failure on the main appliance, or maybe you have different teams that are looking to utilize the appliance in different data centers. In any case, once you install multiple appliances there's another requirement that will pop up pretty quickly. Naturally you are going to want to share custom artifacts among the various WebSphere CloudBurst boxes.
When I say custom artifacts, namely I mean virtual images, patterns, and script packages. Script packages have been easy enough to share since WebSphere CloudBurst 1.0 because you can simply download the ZIP file from one appliance and upload it to another. However, there are some enhancements in WebSphere CloudBurst 1.1 that make it easy to share both patterns and images among your different appliances.
As far as patterns go, there is a new script included in the samples directory of the WebSphere CloudBurst command line interface package called patternToPython.py. This script will transform a pattern you specify into a python script. The resulting python script can then be run against a different WebSphere CloudBurst (using the CLI), and the result is the pattern is created on the target appliance. You need to be sure that the artifacts that pattern references (script packages and virtual images) exist on the target appliance and have the exact same name as they do on the appliance from which the pattern was taken. There are no other caveats, and this new sample script makes it really simple to move patterns between appliances.
For virtual images, a new feature was added that allows you to export a virtual image from the WebSphere CloudBurst console. Simply select a virtual image, specify a remote machine (any machine with SCP enabled), and click a button to export the image as an OVA file. This OVA file can then be added to another WebSphere CloudBurst catalog using the normal process for adding virtual images. You can see this feature in action here.
Stay tuned for more information about some of the handy new features in WebSphere CloudBurst 1.1. We also should have a comprehensive look at the new release coming soon in a developerWorks article.
The announcement of the new IBM CloudBurst offering coupled with the new WebSphere CloudBurst Appliance may create a bit of confusion for some. However, when both offerings are examined it's pretty plain to see any confusion is caused solely by the similarity of names.
IBM CloudBurst is a holistic cloud offering that includes hardware, software, and services. The hardware provides the physical infrastructure needed to host your private cloud. The software provides the capabilities to effectively utilize and manage the various cloud services, and it provides the self-service capabilities that enable the entire IT staff to provision cloud resources as necessary. The services portion provides IBM expert help in getting started toward utilizing the hardware and software components to effectively build a private cloud.
The WebSphere CloudBurst Appliance on the other hand is devoted to allowing users to create, deploy, and manage WebSphere middleware environments in a private cloud. It does not provide the infrastructure necessary to host a private cloud, rather it relies on users to bring their own cloud. In that sense, the WebSphere CloudBurst Appliance could be seen as a subset of the IBM CloudBurst offering, specifically as part of the cloud service management capabilities of IBM CloudBurst. The appliance would utilize the hardware portion of the IBM CloudBurst offering as the cloud infrastructure for the WebSphere middleware environments it dispenses.
Couple the hardware and cloud service management capabilities provided by these two offerings along with IBM experts via IBM CloudBurst's services portion, and users can quickly build out and leverage private enterprise clouds.
If you are interested, I encourage you to visit the landing page for both IBM CloudBurst and the WebSphere CloudBurst Appliance. Both offerings are truly unique, and they promise to make private enterprise clouds a reality.
When it comes to IBM Workload Deployer, I have no illusions concerning our competitors. They are out there, and they are constantly on the attack. Their dubious claims aside, I know this because I still get asked quite frequently to explain the benefits of IBM Workload Deployer versus some other general purpose cloud provisioning and management solution. So, while I have done that many times in various forums, I figured it was time to address the subject here on the blog.
When comparing IBM Workload Deployer to the other available solutions, I honestly feel comfortable saying we have no direct competition. I know you believe me to be biased, and rightly so, but let me explain why I think the competition is much more perception than reality. To do this, I want to focus on the patterns-based approach that IBM Workload Deployer takes to cloud provisioning and management.
Let's start with virtual system patterns in IBM Workload Deployer. Virtual system patterns allow you to build and deploy completely configured and integrated middleware environments as a single unit. These patterns build on top of our special IBM Hypervisor Edition images that bottle up the installation and quite a bit of the configuration of the underlying middleware products. Further, when using virtual system patterns, IBM Workload Deployer manages and automates the orchestration of the integration tasks that need to happen to setup a meaningful middleware environment. For instance, when deploying WebSphere Application Server you do not need to do anything on your end to deploy a clustered, highly available environment. When deploying WebSphere Process Server in this manner, you do not need to take any administrative actions to produce a golden topology. You just deploy patterns and the images, patterns, and appliance take care of the rest. Of course, you can add your own customizations and tweaks in the pattern, but we take care of the common administrative actions that would otherwise require your care.
I am not sure of a better way to say it, so I will be blunt: When deploying products delivered in IBM Hypervisor Edition form, no other solution compares to the virtual system pattern capability offered by IBM Workload Deployer. It is not even close. Can you provision products like WebSphere Application Server or WebSphere Portal using other cloud provisioning tools? Sure, but you should be aware that you will be writing and maintaining your own installation, configuration, and integration scripts. It is also likely that you will end up developing a custom interface through which deployers request your services (something not necessary when using the slick IBM Workload Deployer UI). All of this takes time, resource, and money. More importantly, this is not differentiating work and distracts from the real end goal: serving up applications. IBM Workload Deployer can deliver this operational capability right out of the box, and it can do so in a way that costs less than custom developed and maintained solutions.
When considering IBM Workload Deployer versus the competition, it is also important to consider the new virtual application pattern capability delivered in version 3.0. The virtual application pattern capability is a testament to IBM's thought leadership in and commitment to cloud computing for middleware application environments. Virtual application patterns take a bold step forward in raising the level of abstraction beyond the middleware environment and up to the most important resource in enterprise environments: the application. With a virtual application pattern, you simply provide your application and specify both functional and non-functional requirements for that application. When ready, you deploy that pattern, and IBM Workload Deployer sets up the necessary middleware infrastructure and deploys the provided application. Moreover, the appliance will monitor and autonomically manage the environment (i.e. scale it up and down) based on the policies you specify. Quite simply, this is a deployment and management capability our competition cannot match.
There is more to consider than just patterns though. The appliance makes it really simple to apply maintenance and upgrades to environments running in your cloud. It can autonomically manage your deployed environments (through policies in virtual application patterns and the Intelligent Management Pack for virtual system patterns), and it effectively abstracts the underlying infrastructure of your cloud environment. This abstraction is the reason IBM Workload Deployer can deploy your environments to PowerVM, zVM, and VMware environments. It also makes it easy to deploy the same environment to multiple different underlying platforms, thus accommodating typical platform changes that happen as an application moves from development to production. The best part of all is that the deployer’s experience is the same regardless of the underlying infrastructure since the appliance hides any platform idiosyncrasies.
The bottom line is that the appliance is purpose built to deploy and manage middleware and middleware application environments in a cloud, and as such, delivers immense out-of-the-box and ongoing value in this context. I should also point out that the design of the appliance acknowledges its purposeful nature. The CLI and REST API interfaces allow you to integrate the appliance into the operations of those general purpose provisioning solutions. In this way, IBM Workload Deployer acts as a middleware accelerator for your cloud computing efforts. This means that if you do have a general purpose solution, IBM Workload Deployer can still provide considerable value and let you avoid developing a considerable subsystem dedicated to deployment and management of middleware in the cloud. We believe in this type of integration, and have in fact built it into our own IBM solutions.
I could go on and on differentiating IBM Workload Deployer from the competition, but I hope my comments above give you a good context on why I think the appliance is in a league of its own. Of course, I always appreciate comments and feedback, so don't be shy!
There have been quite a few announcements from IBM lately that keep referring to the "IBM Cloud". Since IBM has been moving at a pretty substantial pace with cloud offerings as of late, I thought it may help to give readers a concise idea of exactly what the IBM Cloud provides.
Put very simply, the IBM Cloud is a public cloud offering that allows users to provision and utilize IBM Software on an infrastructure hosted by IBM. From the IBM Cloud's web-based dashboard, users choose a software package, provide some deployment information about the particular instance they wish to create, and then simply click OK. In a matter of minutes the software is up, running, and available for full use. At the time I wrote this blog, I saw software from our Information Management, Rational, and WebSphere brands available for use. In addition, users can launch plain SUSE Linux instances out onto the IBM Cloud.
Within WebSphere, users can choose from either the WebSphere Application Server or WebSphere sMash. I just went through a WebSphere sMash deployment, and in about 6 minutes the sMash instance was up and running, and I was able to log into the App Builder development environment. The WebSphere Application Server package that's available on the IBM Cloud is particularly interesting because it contains an embedded Rational Controller Agent. This makes it very easy to integrate some of the Rational offerings on the IBM Cloud (or elsewhere) with the WebSphere Application Server. Many of these integration scenarios focus on making it easier to very quickly build, package, and deploy applications from Rational development tooling to WebSphere Application Server environments.
The best thing about the IBM Cloud is that you can sign up and give it a whirl with absolutely no costs! Go and sign up for a free account and you'll immediately be able to spin up IBM Software in IBM's cloud. You can access and use that software, and then when you are done you can simply delete the running instance. There's no need to download anything to your computer, the interface to the IBM Cloud is completely web-based, and the launched software runs on IBM infrastructure. All of this adds up to give users a super easy way to kick the tires on some of our software. Sign up now by visiting the landing page for the IBM Cloud.
A few weeks ago, I had a conversation with a current WebSphere customer about the potential value they could derive from the use of IBM Workload Deployer. Right away, this customer saw value in the consistency that a patterns-based approach could afford them. It was clear that patterns eliminate the uncertainty that can make its way into even the best-planned deployment processes. Initially though, the customer questioned the value of being able to do fast deployments because, in their words, "We don't deploy WebSphere environments that often." So, we continued our discussion, and then they asked an important question that I encourage all of our users to ask: "Why don't we deploy our WebSphere environments more frequently?"
It is interesting to talk with our WebSphere users that have a long history with our products. Often times, they have been taking a shared approach to WebSphere installations for many, many years. They develop innovative approaches and isolation schemes that allow them to carve up a single WebSphere installation (cell) amongst multiple different application teams. This allows them to avoid having to setup a cell for each application deployment and saves them the associated time. However, having talked to many different users taking this approach, it is not without its challenges.
As was the case in the customer I mention above, users typically made trade-offs when electing for larger, shared cells. As an example, if you have multiple different application teams with different types of applications using a single cell, applying fixes and upgrades to that cell can be a lot more complex. After all, you now have to coordinate plans across a number of different teams and find a window that fits all of their needs. For the same reason, trying incremental function via our feature packs is much more arduous in these types of cells. Additionally, administrative controls become more complex since teams with varying needs all require administrative access. Admittedly, this gets simpler with newer fine-grained security models in WebSphere Application Server v7 and v8, but it still requires organizational discipline and process.
At this point I should be clear that I am not denigrating the shared cell approach. It can work well, and we have many facilities built into the WebSphere Application Server product to support that model. However, if you are using this approach and you find yourself stumbling too much for your own liking, then I would strongly suggest that you explore the patterns-based approach of IBM Workload Deployer. By deploying patterns that represent your WebSphere cells using IBM Workload Deployer, you can quickly and consistently setup multiple WebSphere Application Server cells to support the varying needs of your application teams. You will still avoid spending an inordinate amount of time installing and configuring cells as that is an automated part of pattern deployment, and your application teams will still get the resources they need. Further, this can liberate your application teams in terms of how they apply maintenance, install upgrades, and absorb new function in the form of feature packs.
I am not suggesting a complete pendulum swing in your approach to how you manage multiple application environments. There is definitely a happy medium in terms of how many cells you end up with. After all, you do not want to trade in one set of problems for the problem of managing way too many different cells. However, I do think that decomposing monolithic, multi-purpose cells into smaller, more purposeful cells can be beneficial. In the course of thinking about this different approach, you may come to the same conclusion that the customer I mention above did. IBM Workload Deployer's rapid deployment capabilities are indeed valuable if you take a slightly different view of current processes.
I'm out at the RSA conference in San Francisco this week, and I'm expecting a lot of good conversations about WebSphere CloudBurst and security. This topic always comes up when I'm out and talking to customers, and I approach it from a few different angles.
First of all, WebSphere CloudBurst enables the creation of on-premise clouds (clouds in your data center). This means that you retain control over the resources that make up and support your cloud, and you have the ability to very tightly secure said resources. Notice that I say "you have the ability". I'm careful to point out that on-premise clouds do not inherently make your environment secure. If you don't already have a robust security strategy in place within your enterprise, then simply moving to a cloud model will not solve much. That being said, if you do have a comprehensive security strategy in place, one built around customized processes and access rights, then on-premise clouds are likely to make much more sense for you.
Moving beyond the opportunity for customized security controls provided by on-premise clouds, WebSphere CloudBurst delivers additional, unique security features. It starts on the outside with the tamper-resistant physical casing. If a malicious user attempts to remove the casing to get to the inner contents, the appliance is put into a dormant state, and it must be sent to IBM to be reset. "So what!" you say. If the user removes the casing and gets to the contents, couldn't they simply read the contents off the flash memory or hard disks directly, or insert them into another WebSphere CloudBurst Appliance and read them from there? Nope. All of the contents stored on the appliance's flash memory and hard disks are encrypted with a private key that cannot be changed and is unique to each and every appliance.
If you are at all familiar with WebSphere CloudBurst, you know that the appliance dispenses and monitors virtual systems running on a collection of hypervisors. Obviously then, the appliance must remotely communicate with the hypervisors. In order to secure this communication, all information between WebSphere CloudBurst and the hypervisors (and vice versa) is encrypted. This encryption is achieved by using an SSL certificate that is exchanged when a hypervisor is defined in WebSphere CloudBurst. This certificate must be accepted by a user, thus preventing rogue hypervisors from being defined in WebSphere CloudBurst.
Finally, WebSphere CloudBurst provides for the definition of users and user groups with varying permissions and resource access rights in the appliance. You don't have to turn over the keys to your cloud kingdom when you add a user to the appliance. You have the capability to define varying permissions (from simply deploying patterns, to creating them, all the way up to administering the cloud and appliance), and you have the ability to control access to resources (patterns, virtual images, script packages, cloud groups, etc.) at a fine-grained level. These two capabilities combine to allow you to control not only what actions a user can take, but also on which resources they can take those actions.
WebSphere CloudBurst was designed with focus on delivering a secure cloud experience, and I think it hit the mark. I'm sure I didn't address all your WebSphere CloudBurst and security related questions. If you have something specific in mind, leave a comment on the blog or reach out to me on Twitter. I'll do my best to address your question.
Many technologies and ideas are paving the way for cloud computing. Utility computing, grid computing, and virtualization have all played important roles in enabling cloud solutions to take hold. In some ways, SOA is an easy to overlook player in the cloud computing world. However, there's no doubt that without SOA, and the ideas from the SOA movement, cloud computing would not be where it is now.
First, consider the millions of services available in the application services layer of the public cloud. While some of these services are intended to be consumed by an end-user, just as many are meant to be consumed programmatically. Enterprises seek to compose services in the application services layer to deliver larger, end-user applications to their consumers. As such, the ability to consume services that exist across domains and company firewalls is a must. SOA standards help in this respect as they define how services, regardless of location, are discovered, consumed, and governed. This common set of standards has helped to make the services in a public cloud more readily useable by enterprises, so SOA standards have been a key factor in the explosion of service offerings in the public cloud.
Second, and just as important, is the impact that SOA has and will continue to have on the enabling layers of cloud computing. By the enabling layers of the cloud, I mean the platform and infrastructure services layer where we find both application and physical infrastructure. These two layers in the cloud are often referred to as constituting a Service Oriented Infrastructure, so the impact of SOA is immediately obvious. SOA has led to viewing application and physical infrastructure capabilities as discrete services that can be consumed as part of an overall solution or process. As the number of services in these two layers continues to grow, it will be important that they can be discovered, managed, and governed similar to software service components so as to enable robust, composable cloud infrastructure solutions. By applying the principles and lessons of SOA to these enabling services, we can achieve a discoverable, composable, and governable cloud infrastructure.
SOA should be acknowledged as a key enabler to cloud computing solutions. There are of course reasons beyond what is mentioned above. For instance, think about application virtualization and how effective management of such virtualization requires the capability to interact with applications implemented in various technologies. SOA standards have established how to interact and communicate with applications regardless of implementation, so virtualization management can and should piggyback on these standards. As cloud computing continues to evolve, I think we will only see more instances of SOA affecting cloud computing for the better.