Microservices in Practice: From Architecture to Deployment

Microservices is one of the most popular buzz-words in the field of software architecture. There are numerous learning materials on the fundamentals and benefits of microservices, but there are very few resources on how you can use microservices in real-world enterprise scenarios.

In this post, I'm going to cover the key architectural concepts of the Microservices Architecture (MSA) and how you can use those architectural principles in practice.

Monolithic Architecture

Enterprise software applications are designed to facilitate numerous business requirements; a given software application offers hundreds of functionalities and all such functionalities are piled into a single monolithic application. For example, ERPs, CRMs, and other various software systems are built as a monolith with several hundreds of functionalities. The deployment, troubleshooting, scaling, and upgrading of such monstrous software applications is a nightmare.

Service Oriented Architecture (SOA) was designed to overcome some of the aforementioned limitations by introducing the concept of a service, an aggregation and grouping of similar functionalities offered from an application. With SOA, a software application is designed as a combination of coarse-grained services. However, in SOA, the scope of a service is very broad. That leads to complex and mammoth services with several dozens of operations (functionalities), along with complex message formats and standards (e.g: all WS* standards).

In most cases, services in SOA are independent of each other; yet they are deployed in the same runtime along with all other services (just think about having several web applications that are deployed into the same Tomcat instance). Similar to monolithic software applications, these services have a habit of growing over time by accumulating various functionalities. Literally, that turns those applications into monolithic globs that are no different from conventional monolithic applications such as ERPs. The shows a retail software application which comprises of multiple services. All these services are deployed into the same application runtime. So, it's a very good example of a monolithic architecture. Here are some of the characteristics of applications based on monolithic architecture.

• Monolithic applications are designed, developed, and deployed as a single unit.
• Monolithic applications are overwhelmingly complex; this leads to nightmares in maintaining, upgrading, and adding new features.
• It is difficult to practice agile development and delivery methodologies with Monolithic architecture.
• It is required to redeploy the entire application in order to update a part of it.
• The application has to be scaled as a single unit, making it difficult to manage conflicting resource requirements (e.g. one service requires more CPU, while the other requires more memory)
• One unstable service can bring the whole application down.
• It's really difficult to adopt new technologies and frameworks, as of all the functionalities have to build on homogeneous technologies/frameworks.

Microservices Architecture

The foundation of microservices architecture (MSA) is about developing a single application as a suite of small and independent services that are run in their own process, developed, and deployed independently.

In most of the definitions of microservices architecture, it is explained as the process of segregating the services available in the monolith into a set of independent services. However, in my opinion, Microservices is not just about splitting the services available in monolith into independent services.

The key idea is that by looking at the functionalities offered from the monolith, we can identify the required business capabilities. Then those business capabilities can be implemented as fully independent, fine-grained, and self-contained (micro)services. They might be implemented on top of different technology stacks and each service is addressing a very specific and limited business scope.

Therefore, the online retail system scenario that we explain above can be realized with microservices architecture, as depicted in the figure below. With microservice architecture, the retail software application is implemented as a suite of microservices. So, as you can see below, based on business requirements, there is an additional microservice created from the original set of services that are there in the monolith. So, it is quite obvious that using microservices architecture is something beyond the splitting of the services in the monolith.

Let's dive deep into the key architectural principles of microservices, and more importantly, let's focus on how they can be used in practice.

Designing Microservices: Size, Scope, and Capabilities

You may be building your software application from scratch by using Microservices Architecture, or you may be converting existing applications/services into microservices. Either way, it is quite important that you properly decide the size, scope, and capabilities of the Microservices. Probably, that is the hardest thing that you initially encounter when you implement Microservices Architecture in practice.

Let's discuss some of the key practical concerns and misconceptions related to the size, scope, and capabilities of microservices.

• Lines of Code/Team size are lousy metrics: There are several discussions on deciding the size of the Microservices based on the lines-of-code of its implementation or its team's size (i.e. two-pizza team). However, these are considered to be very impractical and lousy metrics, because we can still develop services with less code/with two-pizza-team size but totally violating the microservice architectural principals.
• "Micro" is a bit misleading term: Most developers tend to think that they should try to make the service as small as possible. This is a misconception.
• SOA context: In the SOA context, services are often implemented as monolithic globs with the support for several dozens of operations/functionalities. So, having SOA-like services and rebranding them as microservices is not going to give you any benefits of microservices architecture.

So, then how should we properly design services in Microservices Architecture?

Guidelines for Designing Microservices

• Single Responsibility Principle(SRP): Having a limited and focused business scope for a microservice helps us to meet agility in development and delivery of services.
• During the designing phase of the microservices, we should find their boundaries and align them with business capabilities (also known as bounded context in Domain-Driven-Design).
• Make sure the microservices design ensures the agile/independent development and deployment of the service.
• Our focus should be on the scope of the microservice but not about making the service smaller. The (right) size of the service should be the required size to facilitate a given business capability.
• Unlike service in SOA, a given microservice should have very few operations/functionalities and a simple message format.
• It is often a good practice to start with relatively broad service boundaries to begin with and then refactor to smaller ones (based on business requirements) as time goes on.

In our retail use case, you can find that we have split the functionalities of the monolith into four different microservices, namely "inventory," "accounting," "shipping," and "store." They are addressing a limited but focused business scope so that each service is fully decoupled from each other and ensures the agility in development and deployment.

Messaging in Microservices

In monolithic applications, business functionalities of different processors/components are invoked using function calls or language-level method calls. In SOA, this was shifted towards a much more loosely coupled web service level messaging, which is primarily based on SOAP on top of different protocols such as HTTP, JMS. Webservices with several dozens of operations and complex message schemas was a key resistive force for the popularity of web services. For Microservices architecture, it is required to have a simple and lightweight messaging mechanism.

Synchronous Messaging - REST, Thrift

For synchronous messaging (client expects a timely response from the service and waits till it get it) in Microservices Architecture, REST is the unanimous choice as it provides a simple messaging style implemented with HTTP request-response, based on resource API style. Therefore, most microservices implementations are using HTTP along with resource API based styles (every functionality is represented with a resource and operations carried out on top of those resources).

Thrift is used (in which you can define an interface definition for your microservice), as an alternative to REST/HTTP synchronous messaging.

Asynchronous Messaging - AMQP, STOMP, MQTT

For some microservices scenarios, it is required to use asynchronous messaging techniques (client doesn't expect a response immediately, or does not accept a response at all). In such scenarios, asynchronous messaging protocols such as AMQP, STOMP, or MQTT are widely used.

Message Formats - JSON, XML, Thrift, ProtoBuf, Avro

Deciding the best message format for Microservices is another key factor. The traditional monolithic applications use complex binary formats, SOA/Web services-based applications use text messages based on complex message formats (SOAP) and schemas (xsd). In most microservices-based applications, they use simple text-based message formats, such as JSON and XML on top of HTTP resource API style. In cases where we need binary message formats (text messages can become verbose in some use cases), microservices can leverage binary message formats such as binary Thrift, ProtoBuf, or Avro.

Service Contracts - Defining the Service Interfaces - Swagger, RAML, Thrift IDL

When you have a business capability implemented as a service, you need to define and publish the service contract. In traditional monolithic applications, we barely find such features to define the business capabilities of an application. In SOA/Web services world, WSDL is used to define the service contract, but, as we all know, WSDL is not the ideal solution for defining microservices contract as WSDL is insanely complex and tightly coupled to SOAP.

Since we build microservices on top of a REST architectural style, we can use the same REST API definition techniques to define the contract of microservices. Therefore, microservices use the standard REST API definition languages, such as Swagger and RAML to define the service contracts.

For other microservices implementation that are not based on HTTP/REST (such as Thrift), we can use the protocol level Interface Definition Languages(IDL) (e.g.: Thrift IDL).

Integrating Microservices (Inter-service/process Communication)

In Microservices architecture, the software applications are built as a suite of independent services. So, in order to realize a business use case, it is required to have the communication structures between different microservices/processes. That's why inter-service/process communication between microservices is such a vital aspect.

In SOA implementations, the inter-service communication between services is facilitated with an Enterprise Service Bus (ESB) and most of the business logic resides in the intermediate layer (message routing, transformation, and orchestration). However, Microservices architecture promotes to eliminate the central message bus/ESB and move the "smart-ness" or business logic to the services and client (known as Smart Endpoints).

Since microservices use standard protocols such as HTTP, JSON, etc. the requirement of integrating with a disparate protocol is minimal when it comes to the communication among microservices. Another alternative approach in Microservice communication is to use a lightweight message bus or gateway with minimal routing capabilities and act as a "dumb pipe" with no business logic implemented on the gateway. Based on these styles, there are several communication patterns that have emerged in microservices architecture.

Point-to-point Style - Invoking Services Directly

In point to point style, the entirety of the message routing logic resides on each endpoint and the services can communicate directly. Each microservice exposes a REST APIs and a given microservice or an external client can invoke another microservice through its REST API.

Obviously, this model works for relatively simple microservices-based applications, but as the number of services increases, this will become overwhelmingly complex. After all, that's the exact reason for using ESB in the traditional SOA implementation: to get rid of the messy point-to-point integration links. Let's try to summarize the key drawbacks of the point-to-point style for microservice communication.

• The non-functional requirements such as end-user authentication, throttling, monitoring, etc. has to be implemented at each and every microservice level.
• As a result of duplicating common functionalities, each microservice implementation can become complex.
• There is no control at all of the communication between the services and clients (even for monitoring, tracing, or filtering)
• Often the direct communication style is considered as a microservice anti-pattern for large scale microservice implementations.

Therefore, for complex Microservices use cases, rather than having point-to-point connectivity or a central ESB, we could have a lightweight central messaging bus which can provide an abstraction layer for the microservices and that can be used to implement various non-functional capabilities. This style is known as API Gateway style.

API-Gateway Style

The key idea behind the API Gateway style is that using a lightweight message gateway as the main entry point for all the clients/consumers and implement the common non-functional requirements at the Gateway level. In general, an API Gateway allows you to consume a managed API over REST/HTTP. Therefore, here we can expose our business functionalities which are implemented as microservices, through the API-GW, as managed APIs. In fact, this is a combination of Microservices architecture and API-Management which give you the best of both worlds.