This three-part series was written by Mina Andrawos, author of “Cloud Native programming with Golang,” which provides practical techniques and architectural patterns for cloud native micro-services. He’s also the author of the “Mastering Go Programming” and the “Modern Golang Programming” video courses.
This series hopes to shed some light and provide practical input on some key topics in the modern software industry, namely micro-services, cloud native applications, containers and serverless applications. It will cover both practical advantages and disadvantages of these technologies.
Micro-services
Micro-service architecture has gained a reputation as a powerful approach for building modern software applications. So what are micro-services? Micro-services separate the functionality required from a software application into multiple independent small software services. Each of these micro-services is responsible for an individual focused task. In order for micro-services to work together to form a large scalable application, they must communicate and exchange data among multiple servers, a practice known as horizontal scaling.
Each service can be deployed on a different server with dedicated resources or in separate containers (more on that below.) These services can be written in different programming languages, enabling greater flexibility and allowing separate teams to focus on each service, rendering the final application of higher quality.
Another notable advantage to using micro-services is the ease of continuous delivery, or the ability to deploy software often and at any time. Micro-services make continuous delivery easier because a new feature deployed to one micro-services is less likely to affect other micro-services.
Cloud native applications
Micro-service architectures are a natural fit for cloud native applications — applications built from the ground up for cloud computing. An application is cloud native if designed with the expectation of deploying on a distributed and scalable infrastructure.
For example, building an application with a redundant micro-services architecture – we’ll see an example shortly – makes the application cloud native, since this architecture allows our application to be deployed in a distributed manner that allows it to be scalable and almost always available. A cloud native application doesn’t need to always be deployed to a public cloud like Amazon Web Services, it can be deployed to distributed cloud-like infrastructure as well.
In fact, what makes an application fully cloud native goes beyond just using micro-services. Your application should employ continuous delivery, the ability to continuously deliver updates to your production applications without disruptions. Your application should also make use of services like message queues and technologies like containers (covered in the next section).
Cloud native applications assume access to numerous server nodes, having access to pre-deployed software services like message queues or load balancers, ease of integration with continuous delivery services, among other things.
If you deploy your cloud native application to a commercial cloud like AWS or Azure, your application has the option to utilize cloud-only software services. For example, DynamoDB is a powerful database engine that can only be used on AWS for production applications. Another example is the DocumentDB database in Azure. There are also cloud-only message queues such as Amazon Simple Queue Service (SQS), that can be used to allow communication between micro-services in the Amazon Web Services cloud.
As mentioned earlier, cloud native micro-services should be designed to allow redundancy between services. If we take the events booking application as an example, the application will look like this:
Multiple server nodes would be allocated per micro-service, allowing a redundant micro-services architecture to be deployed. If the primary node or service fails for any reason, the secondary can take over ensuring lasting reliability and availability for cloud native applications. This availability is vital for fault intolerant applications such as e-commerce platforms, where downtime translates into lost revenue.
A notable tool worth mentioning in the world of micro-services and cloud computing is Prometheus. Prometheus is an open-source system monitoring and alerting tool that can be used to monitor complex micro-services architectures and send alerts when action needs to be taken. Originally created by SoundCloud to monitor their systems it grew to become an independent project and is now a part of the Cloud Native Computing Foundation.
Containers
A container is simply the idea of encapsulating some software inside an isolated user space or “container.” For example, a MySQL database can be isolated inside a container where the environmental variables and the configurations that it needs will live. Software outside the container will not see the environmental variables or configuration contained inside the container by default. Multiple containers can exist on the same local virtual machine, cloud virtual machine, or hardware server.
Containers provide the ability to run numerous isolated software services, with all their configurations, software dependencies, run times, tools, and accompanying files, on the same machine. In a cloud environment, this ability translates into saved costs and efforts, because the need for provisioning and buying server nodes for each micro-services will diminish since different micro-services can be deployed on the same host without disrupting each other. Containers combined with micro-services architectures are powerful tools to build modern, portable, scalable and cost-efficient software. In a production environment, more than a single server node combined with numerous containers would be needed to achieve scalability and redundancy.
Containers add more benefits to cloud native applications. With a container, you can move your micro-services, with all the configuration, dependencies and environmental variables that it needs, to fresh server nodes without the need to reconfigure the environment, achieving powerful portability.
Due to the power and popularity of the software containers technology, some new operating systems like CoreOS or Photon OS are built from the ground up to function as hosts for containers.
One of the most popular software container projects in the software industry is Docker. Major organizations such as Cisco, Google and IBM utilize Docker containers in their infrastructure as well as in their products. Another notable project in the software containers world is Kubernetes. Kubernetes is a tool that allows the automation of deployment, management, and scaling of containers. Built by Google to facilitate the management of their containers, Kubernetes provides some powerful features such as load balancing between containers, restart for failed containers, and orchestration of storage utilized by the containers.
Disadvantages of cloud native computing
It’s important to a point out the disadvantages of these technologies. One notable drawback of relying heavily on micro-services is that they can become too complicated to manage in the long run as they grow in numbers and scope. There are approaches to mitigate this by utilizing monitoring tools such as Prometheus to detect problems, container technologies such as Docker to avoid polluting the host environments and avoid over-designing the services. However, these approaches take effort and time.
For cloud native applications, if the need arises to migrate some or all of the applications, some challenges will be faced. There are multiple reasons for that, depending on where your application is deployed.
One is that if your cloud native application is deployed on a public cloud like AWS, cloud native APIs are not cross-cloud platform. For example, a DynamoDB database API utilized in an application will only work on AWS but not Azure, since DynamoDB only belongs to AWS. The API will also never work in a local environment because DynamoDB can only be utilized in AWS in production.
Another reason is that there are some assumptions made when some cloud native applications are built, such as the fact that there will be virtually unlimited number of server nodes to utilize when needed and that a new server node can be made available very quickly. These assumptions are sometimes hard to guarantee in a local data center environment, where real servers, networking hardware and wiring need to be purchased.
In the case of containers, sometimes the task of managing them can get rather complex for the same reasons as managing expanding numbers of micro-services. As containers or micro-services grow in size, there needs to be a mechanism to identify where each container or micro-services is deployed, what their purpose is and what they need in resources to keep running.
Serverless applications
Serverless architecture is a new software architectural paradigm that was popularized with the AWS Lambda service. To fully understand serverless applications, let’s start by defining function-as-a-service (FaaS.) This is the idea that a cloud provider such as Amazon or even a local piece of software such as Fission.io or funktion provides a service where a user can request a function to run remotely in order to perform a very specific task and then after the function concludes, the function results return back to the user. No services or stateful data are maintained and the function code is provided by the user to the service that runs the function.
The idea of a properly designed production applications that utilize the serverless architecture is that instead of building multiple micro-services expected to run continuously in order to carry out individual tasks, build an application that has fewer micro-services combined with FAAS for tasks that don’t need services to run continuously.
FAAS is smaller construct than a micro-service. For example, in case of the event booking application we covered earlier, there were multiple micro-services covering different tasks. If we use a serverless applications model, some of those micro-services would be replaced with a number of functions that serve their purpose. For example, here’s a diagram that showcases the application utilizing a serverless architecture:
In this diagram, the event handler acts as micro-services as well as the booking handler — micro-services were replaced with a number of functions that produce the same functionality. This eliminates the need to run and maintain the two existing micro-services.
Such a monolithic application will work well with small to medium loads. It can run on a single server, connect to a single database and will be written probably in the same programming language.
Now, what happens if business booms and hundreds of thousands or millions of users need to be handled and processed? Initially, the short-term solution is to ensure that the server on which the application runs has powerful hardware specifications to withstand higher loads with vertical scaling (the act of increasing hardware specifications like RAM and hard drive to run heavy applications). Typically, though, it’s not sustainable as the load on the application continues to grow.
Another challenge with monolithic applications is the inflexibility caused by being limited to only one or two programming languages. This inflexibility can affect the overall quality and efficiency of the application. For example, node.js is a popular JavaScript framework for building web applications, whereas R is popular for data science applications. A monolithic application will make it difficult to utilize both technologies, whereas in a micro-services application, you can simply build a data science service written in R and a web service written in Node.js.
A third notable challenge with monolithic applications is collaboration. For example, in the event booking application, a change that caused a bug in the single front-end user interface layer could affect the other pieces of the application using it like the search, events and bookings handlers.
If you were to create a micro-services version of the events application it would take the below form:
This application will be capable of horizontal scaling among multiple servers. Each service can be deployed on a different server with dedicated resources, or in separate containers.
How do micro-services work with cloud native applications?
Micro-service architectures are a natural fit for cloud native applications. A cloud native application is simply defined as an application built from the ground up to run on a cloud platform. A cloud platform has numerous advantages such as obtaining multiple server nodes at a moment’s notice without the pains of IT hardware infrastructure planning. Building your application in a microservices architecture is an important step to develop scalable cloud native applications.
Another feature of cloud native applications is utilizing cloud only software services. For example, DynamoDB is a powerful database engine that can only be used on Amazon Web Services for production applications. Another example is the DocumentDB database in Azure. There are also cloud native message queues such as Amazon Simple Queue Service (SQS), which can be used to allow communication between micro-services in the Amazon Web Services cloud.
Cloud native micro-services can also be designed to allow redundancy between services. If we take the events booking application as an example, the application would look like this:
Because obtaining new server nodes is not a hardware infrastructure challenge, multiple server nodes could be allocated per micro-service. If the primary node or service fails for any reason, the secondary can take over, ensuring lasting reliability and availability for cloud native applications. The key here is availability for fault intolerant applications such as e-commerce platforms where downtime translates into lost revenue.
Micro-services cloud native applications combine the advantages of micro-services with the benefits of cloud computing to provide great value for developers, enterprises and startups.
Another notable advantage (aside from availability and reliability) is continuous delivery. The reason why micro-services make continuous delivery easier is because a new feature deployed to one micro-service is far less likely to affect other micro-services.
Conclusion
Cloud computing has opened avenues for developing efficient, scalable and reliable software. Here, we’ve covered some significant concepts in the world of cloud computing such as microservices, cloud native applications and serverless applications.
When designing an application, architects must choose whether to build a monolithic application, a microservices cloud native application, or a serverless application. Hopefully, I’ve given you some insight on how to make that decision.
In part two of this series, we’ll dive into cloud-native applications and containers also shed some light on the disadvantages of depending on them. Part three of the series will take you through serverless applications in detail and show you how all three fit in together.
Content courtesy Packt Publishing
The post An overview of micro-services, cloud native, containers and serverless appeared first on Superuser.
That said, someone I respect suggested last weekend that good conference talks are actionable. A talk full of OpenStack war stories isn’t actionable, so I’ve spent the last week re-writing this talk to hopefully be more of a call to action than just an interesting story. I apologise for any mismatch between the original proposal and what I present here that might therefore exist.
