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Designing and Implementing Microsoft DevOps Solutions AZ-400 Exam Guide

You're reading from   Designing and Implementing Microsoft DevOps Solutions AZ-400 Exam Guide Prepare for the certification exam and successfully apply Azure DevOps strategies with practical labs

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Product type Paperback
Published in Sep 2022
Publisher Packt
ISBN-13 9781803240664
Length 490 pages
Edition 2nd Edition
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Authors (4):
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Swapneel Deshpande Swapneel Deshpande
Author Profile Icon Swapneel Deshpande
Swapneel Deshpande
Henry Been Henry Been
Author Profile Icon Henry Been
Henry Been
Maik van der Gaag Maik van der Gaag
Author Profile Icon Maik van der Gaag
Maik van der Gaag
Subhajit Chatterjee Subhajit Chatterjee
Author Profile Icon Subhajit Chatterjee
Subhajit Chatterjee
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Toc

Table of Contents (27) Chapters Close

Preface 1. Part 1 – Digital Transformation through DevOps
2. Chapter 1: Introduction to DevOps FREE CHAPTER 3. Chapter 2: Site Reliability Engineering Fundamentals 4. Chapter 3: Getting the Best Out of DevOps Tools 5. Part 2 – Getting to Continuous Delivery
6. Chapter 4: Everything Starts with Source Control 7. Chapter 5: Moving to Continuous Integration 8. Chapter 6: Implementing Continuous Deployment and Release Management 9. Part 3 – Expanding Your DevOps Pipeline
10. Chapter 7: Dependency Management 11. Chapter 8: Implement Infrastructure and Configuration as Code 12. Chapter 9: Dealing with Databases in DevOps Scenarios 13. Chapter 10: Integrating Continuous Testing 14. Chapter 11: Managing Security and Compliance 15. Part 4 – Closing the Loop
16. Chapter 12: Application Monitoring 17. Chapter 13: Gathering User Feedback 18. Part 5 – Advanced Topics
19. Chapter 14: Adopting the Culture of Continuous Improvement 20. Chapter 15: Accelerate Cloud Adoption through DevOps 21. Chapter 16: Containers 22. Chapter 17: Planning Your Azure DevOps Organization 23. Chapter 18: AZ-400 Mock Exam 24. Assessments 25. Index 26. Other Books You May Enjoy

Exploring DevOps practices and habits

Since you are not the first team going on this journey, you can learn from the experiences of those before you. One example is the Microsoft team that built Azure DevOps. Being in the rare position that they can use their product for developing another product, they have learned a great deal about what makes DevOps successful. From this, they have identified seven key DevOps practices and seven DevOps habits that many successful DevOps teams share:

DevOps Practices

DevOps Habits

Configuration management

Team autonomy and enterprise alignment

Release management

Rigorous management of technical debt

Continuous integration

Focus on the flow of customer value

Continuous deployment

Hypothesis-driven development

Infrastructure as Code

Evidence gathered in production

Test automation

Live-site culture

Application performance monitoring

Myanage infrastructure as a flexible resource

Table 1.2 – DevOps practices and habits

Now, it is important to realize that just copying the motions described here will not guarantee success. Just as with Agile, you will have to spend time to understand these practices and habits, where they come from, and how they contribute to a continuous flow of value to your end users.

Important Note

Microsoft Services has introduced a more comprehensive DevOps Dojo model that aims to categorize the maturity of your DevOps practices. It gives you a good structure on how you should prioritize the DevOps-related investments within your teams. You can read more about it here: https://docs.microsoft.com/en-us/learn/paths/devops-dojo-white-belt-foundation/.

The following sections explore all of these practices and habits in more detail. Keep these in the back of your mind while reading the rest of this book. While the rest of this book will mostly focus on the technical means of how to do things, do not forget that these are only means. The real value comes from your mindset and creating a culture that focuses on creating a continuous flow of value for your customers.

DevOps practices

This section discusses all seven DevOps practices in turn. As you will quickly see, they are highly related, and it is quite hard to practice one without the other. For example, test automation is highly related to continuous integration and continuous deployment.

Important Note

If you plan on taking the AZ-400 exam, mastering all of these practices and performing them using Azure DevOps will help you significantly.

Configuration management

Configuration management is about versioning the configuration of your application and the components it relies on, along with your application itself. Configuration is kept in source control and takes the form of, for example, JSON or YAML files that describe the desired configuration of your application. These files are the input for tools such as Ansible, Terraform, Puppet, or PowerShell DSC, which configure your environment and application. These tools are often invoked from a continuous deployment pipeline.

The desired state can also be reapplied at an interval, even if no changes have been made to the intended configuration. This way, it is ensured that the actual configuration stays correct and that manual changes are automatically revoked. We call this the prevention of configuration drift. Configuration drift occurs over time due to servers being added or removed over time, or manual, ad hoc interventions by administrators. Of course, this implies that intended updates to the configuration are done in source control and only applied using tools.

Configuration management or Configuration as Code (CaC) is highly related to Infrastructure as Code (IaC). The two are often intertwined and on some platforms, the difference between the two may even feel artificial. CaC will be discussed in detail in Chapter 8, Implement Infrastructure and Configuration as Code.

Release management

Release management is about being in control of which version of your software is deployed to which environment. Versions are often created using continuous integration and delivery pipelines. These versions, along with all of the configuration needed, are then stored as immutable artifacts in a repository. From here on, release management tools are used to plan and control how these versions are deployed to one or more environments. Examples of such controls include manual approvals and automated queries of open work and quality checks before allowing deployment to a new environment.

Release management is related to continuous deployment and focuses more on controlling the flow of versions through the continuous deployment pipeline. Chapter 8, Implement Infrastructure and Configuration as Code, will cover CaC as part of release management.

Continuous integration

Continuous integration is a practice where every developer integrates their work with that of the other developers in the team at least once a day and preferably more often. This means that every developer should push their work to the repository at least once a day. A continuous integration build verifies that their work compiles and that all the unit tests run. It is important to understand that this verification should not run only on the code that the developer is working on in isolation. The real value comes when the work is also integrated with the work of others.

When integrating changes often and fast, problems with merging changes are less frequent and if they occur, they are often less difficult to solve. In Chapter 4, Everything Starts with Source Control, you will learn more about how to set up your source control repositories to make this possible. In Chapter 5, Moving to Continuous Integration, you will learn about setting up a continuous integration build.

Continuous deployment

Continuous deployment is the practice of automatically deploying every new version of sufficient quality to production. When practicing continuous deployment, you have a fully automated pipeline that takes in every new version of your application (every commit), results in a new release, and starts deploying it to one or more environments. The first environment is often called test and the final environment is called production.

In this pipeline, multiple steps verify the quality of the software before letting it proceed to the next environment. If the quality is not sufficient, the release is aborted and will not propagate to the next environment. The premise behind this approach is that, in the pipeline, you try to prove that you cannot take the current version to the next environment. If you fail to prove so, you assume it is ready for further progression.

Only when a release has gone through all the environments in the pipeline is it deployed to production. Whenever a release cannot progress to the next environment, that release will be completely canceled. While you might be inclined to fix the reason for the failure and then restart deployment from the point where it failed, it is important not to do so. The changes you made at that point are not validated by all of the controls that the version has already passed through. The only way to validate the new version as a whole is by starting the pipeline from the start. You can see this clearly in the following diagram:

Figure 1.4 – Continuous deployment flow

Figure 1.4 – Continuous deployment flow

In Chapter 6, Implementing Continuous Deployment and Release Management, you will learn about setting up continuous deployment using.

Important Note

The preceding diagram can be found at https://en.wikipedia.org/wiki/Continuous_delivery#/media/File:Continuous_Delivery_process_diagram.svg. The image is by Grégoire Détrez, original by Jez Humble, under CC BY-SA 4.0, at https://creativecommons.org/licenses/by-sa/4.0/.

Infrastructure as Code

When writing an application, the binaries that you are building must be running somewhere on some application host. An example of such an application host can be a web server such as IIS or Apache. Next to an application host, we may need a database and some messaging solution. This is called the infrastructure for our application. When practicing IaC, you are keeping a description of this infrastructure in your source code repository, alongside your application code.

When the time comes to release a new version of the application and you need to make one or more changes to the infrastructure, you are executing this description of your desired infrastructure using tools such as Chef, Puppet, Terraform, Azure Bicep, PowerShell DSC, or Azure ARM templates. The execution of such a description is idempotent, which means that it can be executed more than once, and the result is the same. This is because your description of the infrastructure describes the desired state you want the infrastructure to be in and not a series of steps to be executed. Those steps to be executed, if there are any, are automatically determined by your tool of choice. Applying the desired state can also be done automatically in a continuous deployment pipeline and is often executed before the application code is updated.

The big advantage of this is that you can easily create a new environment where the infrastructure is guaranteed to be the same as in your other environments. Also, the problem of configuration drift, where the infrastructure between your different environments slowly diverges, is no longer possible since every time you apply the desired state again to every environment, it’s forced.

Chapter 8, Implement Infrastructure and Configuration as Code, will discuss IaC in more detail.

Test automation

To continuously deliver value to your end users, you must release fast and often. This has implications for the way you test your application. You can no longer execute manual tests when you release your application every few minutes. This means that you must automate as many of your tests as possible.

You will most likely want to create multiple test suites for the applications that you run at different stages of your delivery pipeline. Fast unit tests that run within a few minutes and that are executed whenever a new pull request is opened should give your team very quick feedback on the quality of their work, and it should catch most of the errors. Next, the team should run one or more slower test suites later in the pipeline to further increase your confidence in the quality of a version of your application.

All of this should limit the amount of manual testing to a bare minimum and allow you to automatically deploy new versions of your application with confidence.

Chapter 10, Integrating Continuous Testing, will cover test automation in detail.

Application performance monitoring

This last practice is all about learning how your application is doing in production. Gathering metrics such as response times and the number of requests will tell you about how the systems are performing. Capturing errors is also part of performance monitoring and allows you to start fixing problems without having to wait on your customers to contact you about them.

In addition to that, you can gather information about which parts of the application are more or less frequently used and whether new features are being picked up by users. Learning about usage patterns provides you with great insights into how customers use your applications and common scenarios they are going through.

Chapter 11, Managing Security and Compliance, and Chapter 12, Application Monitoring, will go into detail about both your application and your users’ behavior in production.

DevOps habits

The seven habits of successful DevOps teams are more concerned with culture and your attitude while developing and delivering software, and less with technical means than DevOps practices are. Still, it is important to know and understand these habits since they will help make DevOps adoption easier.

You will notice that developing these habits will reinforce the use of the practices enumerated previously and the tools you use to implement them. And of course, this holds the other way around as well.

Team autonomy and enterprise alignment

An important part of working Agile is creating teams that are largely self-directed and can make decisions without (too many) dependencies outside the team. Such a team will often include multiple roles, including a product owner that owns one or more features and is empowered to decide on their way forward.

However, this autonomy also comes with the responsibility to align the work of the team with the direction the whole product is taking. It is important to develop ways of aligning the work of tens or hundreds of teams with each other, in such a way that everyone can sail their course but the fleet as a whole stays together as well.

The best-case scenario is that teams take it upon themselves to align to the larger vision, instead of taking directions now and then.

Rigorous management of technical debt

Another habit is that of rigorous management of technical debt. The term debt in itself suggests that there is a cost (interest) associated with the delay in addressing an issue. To keep moving at a constant pace and not slowly lose speed over time, it is crucial to keep the number of bugs or architectural issues to a minimum and only tolerate so much. Within some teams, this is even formalized in agreements. For example, a team can agree that the number of unfixed bugs should never exceed the number of team members. This means that if a team has four members and a fifth bug is reported, no new work will be undertaken until at least one bug has been fixed.

Focusing on the flow of customer value

It is important to accept that users receive no value from code that has been written until they are using it. Focusing on the flow of value to a user means that code must be written, tested, and delivered and should be running in production before you are done. Focusing on this habit can drive cooperation between disciplines and teams.

Hypothesis-driven development

In many modern development methodologies, there is a product owner who is responsible for ordering all of the work in the backlog, based on the business value. This owner, as the expert, is responsible for maximizing the value that’s delivered by the development team by ordering all the items based on the business value (divided by effort).

However, recent research has shown that even though the product owner is an expert, they cannot correctly predict which features will bring the most value to users. Roughly one-third of the work from a team adds value for users, while another third decreases the value. For this reason, you can switch your backlog from features or user stories to the hypothesis you want to prove or disprove. You only create a minimal implementation or even just a hint of a feature in the product and then measure whether it is picked up by users. Only when this happens can you expand the implementation of the feature.

Evidence gathered in production

Performance measurements should be taken in your production environment, not (just) in an artificial load test environment. There is nothing wrong with executing load tests before going to production if they deliver value to you. However, the real performance effort is done in the production environment. It should be measured there and compared with previous measurements.

This also holds for usage statistics, patterns, and many, many other performance indicators. They can all be automatically gathered using production metrics.

Live-site culture

A live-site culture promotes the idea that anything that happens in the production environment takes precedence over anything else. Next, anything that threatens production, is about to go to production, or hinders going to production at any time gets priority. Only when these are all in order is the attention shifted to future work.

Also, a part of a live-site culture is ensuring that anything that disturbed the operation of the service is thoroughly analyzed – not to find out who to blame or fire but to find out how to prevent this from happening again. Prevention is preferably done by shifting left; for example, by detecting an indicator of a repeat incident earlier in the pipeline.

Managing infrastructure as a flexible resource

Finally, a successful DevOps team treats its servers and infrastructure as mutable assets that can be continually changed, upgraded, tuned, or even decommissioned to meet the demands of the business. The ability to do this is fueled by configuration and IaC. This may even go so far as creating a new production environment for every new deployment and just deleting the old production environment after switching all traffic from the old environment to the new one.

Besides keeping these DevOps practices and habits in mind, there are certain stages that you will go through while trying to move to a DevOps culture in your organization. The next section will take you through them.

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Designing and Implementing Microsoft DevOps Solutions AZ-400 Exam Guide - Second Edition
Published in: Sep 2022
Publisher: Packt
ISBN-13: 9781803240664
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