This post was originally published here

In conversations with students and other integration specialists, I’m discovering more and more how confused some people are about the evolution of cloud-based integration technologies. I suspect that cloud-based integration is going to be big business in the coming years, but this confusion will be an impediment to us all.

To address this I want to write a less technical, very casual, blog post explaining where we are today (November of 2015), and generally how we got here. I’ll try to refrain from passing judgement on the technologies that came before and I’ll avoid theorizing on what may come in the future. I simply want to give a timeline that anyone can use to understand this evolution, along with a high-level description of each technology.

I’ll only speak to Microsoft technologies because that’s where my expertise lies, but it’s worth acknowledging that there are alternatives in the marketplace.

If you’d like a more technical write-up of these technologies and how to use them, Richard Seroter has a good article on his blog that can be found here.

Way, way back in October of 2008 Microsoft unveiled Windows Azure (although it wouldn’t be until February of 2010 that Azure went “live”). On that first day, Azure wasn’t nearly the monster it has become.

It provided a service platform for .NET services, SQL Services, and Live Services. Many people were still very skeptical about “the cloud” (if they even knew what that meant). As an industry we were entering a brave new world with many possibilities.

From an integration perspective, Windows Azure .NET Services offered Service Bus as a secure, standards-based messaging infrastructure.

Over the years, Service Bus has been rebranded several times but the core concepts have stayed the same: reduce the barriers for building composite applications, even when their components have to communicate across organizational boundaries. Initially, Service Bus offered Topics/Subscriptions and Queues as a means for systems and services to exchange data reliably through the cloud.

Service Bus Queues are just like any other queueing technology. We have a queue to which any number of clients can post messages. These messages can be received from the queue later by some process. Transactional delivery, message expiry, and ordered delivery are all built-in features.

Sample Service Bus queue

Sample Service Bus queue

I like to call Topics/Subscriptions “smart queues.” We have concepts similar to queues with the addition of message routing logic. That is, within a Topic I can define one or more Subscription(s). Each Subscription is used to identify messages that meet certain conditions and “grab” them. Clients don’t pick up messages from the Topic, but rather from a Subscription within the Topic. A single message can be routed to multiple Subscriptions once published to the Topic.

Sample Service Bus Topic and Subscriptions

Sample Service Bus Topic and Subscriptions

If you have a BizTalk Server background, you can essentially think of each Service Bus Topic as a MessageBox database.

Interacting with Service Bus is easy to do across a variety of clients using the .NET or REST APIs. With the ability to connect on-premises applications to cloud-based systems and services, or even connect cloud services to each other, Service Bus offered the first real “integration” features to Azure.

Since its release, Service Bus has grown to include other messaging features such as Relays, Event Hubs, and Notification Hubs, but at its heart it has remained the same and continues to provide a rock-solid foundation for exchanging messages between systems in a reliable and programmable way. In June of 2015, Service Bus processed over 1 trillion (1,000,000,000,000) messages! (Starts at 1:20)

As integration specialists we know that integration problems are more complex than simply grabbing some data from System A and dumping it in System B.

Message transport is important but it’s not the full story. For us, and the integration applications we build, VETRO (Validate, Enrich, Transform, Route, and Operate) is a way of life. I want to validate my input data. I may need to enrich the data with alternate values or contextual information. I’ll most likely need to transform the data from one format or schema to another. Identifying and routing the message to the correct destination is certainly a requirement. Any integration solution that fails to deliver all of these capabilities probably won’t interest me much.

VETRO Diagram

VETRO Diagram

So, in a world where Service Bus is the only integration tool available to me, do I have VETRO? Not really.

I have a powerful, scalable, reliable, messaging infrastructure that I can use to transport messages, but I cannot transform that data, nor can I manipulate that data in a meaningful way, so I need something more.

I need something that works in conjunction with this messaging engine.

Microsoft’s first attempt at providing a more traditional integration platform that provided VETRO-esque capabilities was Microsoft Azure BizTalk Services (MABS) (to confuse things further, this was originally branded as Windows Azure BizTalk Services, or WABS). You’ll notice that Azure itself has changed its name from Windows Azure to Microsoft Azure, but I digress.

MABS was announced publicly at TechEd 2013.

Despite the name, Microsoft Azure BizTalk Services DOES NOT have a common code-base with Microsoft BizTalk Server (on second thought, perhaps the EDI pieces share some code with BizTalk Server, but that’s about all). In the MABS world we could create itineraries. These itineraries contained connections to source and destination systems (on-premises & cloud) and bridges. Bridges were processing pipelines made up of stages. Each stage could be configured to provide a particular type of VETRO function. For example, the Enrich stage could be used to add properties to the context of the message travelling through the bridge/itinerary.

Stages of a MABS Bridges

Stages of a MABS Bridges

Complex integration solutions could be built by chaining multiple bridges together using a single itinerary.

MABS message flow

MABS message flow

MABS was our first real shot at building full integration solutions in the cloud, and it was pretty good, but Microsoft wasn’t fully satisfied, and the industry was changing the approach for service-based architectures. Now we want Microservices (more on that in the next section).

The MABS architecture had some shortcomings of its own. For example, there was little or no ability to incorporate custom components into the bridges, and a lack of connectors to source and destination systems.

Over the past couple of years the trending design architecture has been Microservices. For those of you who aren’t already familiar with it, or don’t want to read pages of theory, it boils down to this:

“Architect the application by applying the Scale Cube (specifically y-axis scaling) and functionally decompose the application into a set of collaborating services. Each service implements a set of narrowly related functions. For example, an application might consist of services such as the order management service, the customer management service etc.

Services communicate using either synchronous protocols such as HTTP/REST or asynchronous protocols such as AMQP.

Services are developed and deployed independently of one another.

Each service has its own database in order to be decoupled from other services. When necessary, consistency is between databases is maintained using either database replication mechanisms or application-level events.”

So the shot-callers at Microsoft see this growing trend and want to ensure that the Azure platform is suited to enable this type of application design. At the same time, MABS has been in the wild for just over a year and the team needs to address the issues that exist there. MABS Itineraries are deployed as one big chunk of code, and that does not align well to the Microservices way of doing things. Therefore, need something new but familiar!

Azure App Service is a cloud platform for building powerful web and mobile apps that connect to data anywhere, in the cloud or on-premises. Under the App Service umbrella we have Web Apps, Mobile Apps, API Apps, and Logic Apps.

Azure App Service

Azure App Service

I don’t want to get into Web and Mobile Apps. I want to get into API Apps and Logic Apps.

API Apps and logic Apps were publicly unveiled in March of 2015, and are currently still in preview.

API Apps provide capabilities for developing, deploying, publishing, consuming, and managing RESTful web APIs. The simple, less sales-pitch sounding version of that is that I can put RESTful services in the Azure cloud so I can easily use them in other Azure App Service-hosted things, or call the API (you know, since it’s an HTTP service) from anywhere else. Not only is the service hosted in Azure and infinitely scalable, but Azure App Service also provides security and client consumption features.

So, API Apps are HTTP / RESTful services running in the cloud. These API Apps are intended to enable a Microservices architecture. Microsoft offers a bunch of API Apps in Azure App Service already and I have the ability to create my own if I want. Furthermore, to address the integration needs that exist in our application designs, there is a special set of BizTalk API Apps that provide MABS/BizTalk Server style functionality (i.e., VETRO).

What are API Apps?

What are API Apps?

This is all pretty cool, but I want more. That’s where Logic Apps come in.

Logic Apps are cloud-hosted workflows made up of API Apps. I can use Logic Apps to design workflows that start from a trigger and then execute a series of steps, each invoking an API App whilst the Logic App run-time deals with pesky things like authentication, checkpoints, and durable execution. Plus it has a cool rocket ship logo.

What are Logic Apps?

What are Logic Apps?

What does all this mean? How can I use these Azure technologies together to build awesome things today?

Service Bus review

Service Bus review

Service Bus provides an awesome way to get messages from one place to another using either Queues or Topics/Subscriptions.

API Apps are cloud-hosted services that do work for me. For example, hit a SaaS provider or talk to an on-premises system (we call these connectors), transform data, change an XML payload to JSON, etc.

Logic Apps are workflows composed of multiple API Apps. So I can create a composite process from a series of Microservices.

Logic App review

Logic App review

But if I were building an entire integration solution, breaking the process across multiple Logic Apps might make great sense. So I use Service Bus to connect the two workflows to each other in a loosely-coupled way.

Logic Apps and Service Bus working together

Logic Apps and Service Bus working together

And as my integration solution becomes more sophisticated, perhaps I have need for more Logic Apps to manage each “step” in the process. I further use the power of Topics to control the workflow to which a message is delivered.

More Logic Apps and Service Bus Topics provide a sophisticated integration solution

More Logic Apps and Service Bus Topics provide a sophisticated integration solution

In the purest of integration terms, each Logic App serves as its own VETRO (or subset of VETRO features) component. Decomposing a process into several different Logic Apps and then connecting them to each other using Service Bus gives us the ability to create durable, long-running composite processes that remain loosely-coupled.

Doing VERTO using Service Bus and Logic Apps

Doing VERTO using Service Bus and Logic Apps

Today Microsoft Azure offers the most complete story to date for cloud-based integration, and it’s a story that is only getting better and better. The Azure App Service team and the BizTalk Server team are working together to deliver amazing integration technologies. As an integration specialist, you may have been able to ignore the cloud for the past few years, but in the coming years you won’t be able to get away with it.

We’ve all endeavored to eliminate those nasty data islands. We’ve worked to tear down the walls dividing our systems. Today, a new generation of technologies is emerging to solve the problems of the future. We need people like you, the seasoned integration professional, to help direct the technology, and lead the developers using it.

If any of this has gotten you at all excited to dig in and start building great things, you might want to check out QuickLearn Training’s 5-day instructor-led course detailing how to create complete integration solutions using the technologies discussed in this article. Please come join us in class so we can work together to build magical things.