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Google Cloud Certified Professional Cloud Developer Exam Guide

You're reading from   Google Cloud Certified Professional Cloud Developer Exam Guide Modernize your applications using cloud-native services and best practices

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Product type Paperback
Published in Sep 2021
Publisher Packt
ISBN-13 9781800560994
Length 382 pages
Edition 1st Edition
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Author (1):
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Sebastian Moreno Sebastian Moreno
Author Profile Icon Sebastian Moreno
Sebastian Moreno
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Table of Contents (21) Chapters Close

Preface 1. Section 1: Welcome to the Google Cloud Developers' Guide
2. Chapter 1: Google Cloud Platform Developer Fundamentals FREE CHAPTER 3. Chapter 2: Security Fundamentals and Best Practices 4. Section 2: Developing and Modernizing Applications on Google Cloud Platform
5. Chapter 3: Application Modernization Using Google Cloud 6. Chapter 4: Using Cloud Functions and Google App Engine 7. Chapter 5: Virtual Machines and Container Applications on Google Cloud Platform 8. Chapter 6: Managing APIs on Google Cloud Platform 9. Section 3: Storage Foundations
10. Chapter 7: Handling Unstructured Data 11. Chapter 8: Databases and Event Messages in Google Cloud 12. Chapter 9: Data Management and Database Strategies 13. Chapter 10: Optimizing Applications with Caching Strategies on Google Cloud Platform 14. Section 4: SRE for Developers
15. Chapter 11: Logging on Google Cloud Platform 16. Chapter 12: Cloud Monitoring, Tracing, and Debugging 17. Section 5: Analyzing a Sample Case Study
18. Chapter 13: HipLocal Sample Case Study Preparation 19. Chapter 14: Questions and Answers 20. Other Books You May Enjoy

The basics that every developer should know about Google Cloud infrastructure

There are many people who think that programming in the cloud is simply a matter of programming in another environment, but I could not disagree more with that statement.

Depending on which cloud service you use, for example, a virtual machine, Platform as a Service (PaaS), or Function as a Service (FaaS), your code could need to handle life cycles and unexpected program terminations.

When you program in the cloud, you should pay attention not only to good coding but also to which platform or service you are using, since many things can change depending on this factor.

For example, programming in an IaaS service is different from programming in a CaaS or FaaS service. (We will explain what these acronyms mean very shortly.)

In this section, you will learn about the most important differences between the different services offered in the cloud, what the regions and zones are, and why concepts such as high availability and latency are so important in a cloud solution.

Regions and zones

A region is a specific location where you can choose to host your services and computing resources with one or more zones.

A compute cluster (a layer between regions and zones) is a physical infrastructure in a data center with independent power, cooling, network, and security services.

A zone can be hosted in one or more clusters and allows the resource load to be handled and balanced within a region.

Choosing multiple zones and regions allows the application to reduce latency to final users and handle failures, transforming your application into a high-availability service.

If a specific zone presents an outage, your application can keep operating using another zone.

If a specific region presents an outage, your application can keep operating using another zone in another region.

Having instances of your application in multiple regions and zones increases your costs as well as your application's availability.

What is X as a Service?

One of the most important things before starting development in the cloud is to understand what the different types of service are and how the shared responsibility model works. But when we start working in the cloud, we see acronyms everywhere, such as the following:

  • IaaS: Infrastructure as a Service
  • CaaS: Container as a Service
  • PaaS: Platform as a Service
  • FaaS: Function as a Service
  • SaaS: Software as a Service

We will start with IaaS. In this case, the cloud provider gives you an infrastructure, generally represented as a virtual machine with an operating system based on a virtualized image. In this kind of service, there is a charge for use. An example of IaaS on Google Cloud Platform (GCP) is GCE, or Google Compute Engine.

In the case of CaaS, the cloud provider gives us an environment where we can deploy our application images. In this kind of service, there is a charge for use.

With PaaS, the cloud provider will provide us with a platform where we can load a previously compiled artifact and configure exposure rules for services and versions. In this kind of service, there is a charge for use. An example of PaaS on GCP is Google App Engine.

If we decide to use FaaS, the cloud provider will give us a platform where we will only have to code and configure the corresponding dependencies, without the need to compile or generate an image. In this kind of service, there is a charge for the number of executions and the time of these executions. An example of FaaS on GCP is Cloud Functions.

And finally, in the case of SaaS, the cloud provider will deliver the software in such a way that the user can directly consume the functionality. For this kind of service, there may be a charge for use or a subscription. An example of SaaS on GCP is Data Studio:

Figure 1.1 – From IaaS to SaaS

Figure 1.1 – From IaaS to SaaS

When you choose to code using IaaS, you should take care of operating system patches and updates, accepting more responsibilities but also having more options to customize your server. That means more management tasks.

When you choose to code using PaaS, you only need to take care of the business logic of your application, accepting fewer infrastructure responsibilities but also having fewer options to customize your server.

As explained in the introduction to this chapter, each service involves different considerations when we start programming.

Among the most important concepts from the preceding list of services is the control of the execution life cycle of our applications. This was not a concept we needed when we programmed on IaaS, because normally, the servers were always on and it was not necessary to worry about telling the server that our asynchronous executions had finished successfully to turn it off.

This is just one of many points that we will review in this chapter and that will help you to program applications in the different GCP services.

How to reduce latency to your end users

Generally, when we have to solve a problem through coding, the first thing we worry about is that the code does what it has to do, no matter how we achieve it. After this, we focus on ensuring that the code does not have any security vulnerabilities, and finally, we might try to optimize or refactor various methods or functions in the interest of efficiency.

In some cases, this is not enough, and we must plan not only how our code will run in the cloud but also where it will run.

You will probably wonder why some streaming or video services are so fast and others so slow. Various factors may be responsible, such as the speed of the user's internet connection, which unfortunately is not something we can control. However, there is a factor that we can control, and that is how close we can bring the content to our end users.

When a user enters a web page to consume content, and in this particular case we are going to assume that the user decides to consume a video, the user has to go to the source, in this case, the server, to access the content.

Depending on how far the user is from the server where the video is stored, the speed with which they download the content to their computer may be higher or lower. This is known as latency.

The distance between the source and the consumer directly affects the latency, and that is why the closer we bring the source to the consumer, the lower the latency and the higher the speed of consumption of the information.

In GCP (and in most clouds), there is the concept of a Content Delivery Network (CDN), which acts as a content cache. This means that the content is replicated on a different server than the originating one, in order to reduce the requests to the original server and also, in this case, to bring the content closer to the end consumer in order to increase performance.

When content is consumed for the first time, Cloud CDN, the Google Cloud solution CDN implementation, will consult the content on the server to find the source of origin and will replicate it in its nodes so that in future requests, the content is available to be delivered directly to users.

For this feature, Cloud CDN uses a cache key, based on the query URL, to determine whether or not the content the user is trying to access is already replicated on the CDN nodes. This is called a cache hit. When the content is not found, this action is called a cache miss. If you need to configure how long the cache content will exist on the CDN node before revalidating the content at the origin, you can use the Time to Live (TTL) configuration in seconds. The default TTL for content caching is 3,600 seconds (1 hour) and the maximum allowed value is 1 year:

Figure 1.2 – CDN workflow

Figure 1.2 – CDN workflow

In summary, Cloud CDN is a solution that allows us to bring content efficiently from the source to consumers, such as images, videos, and files, by replicating the content in different nodes worldwide in order to reduce response times for the final consumer.

Graceful shutdowns

In the world of microservices applications, containerized applications controlled by an orchestrator are generally used. The best-known one is Kubernetes. Kubernetes has the ability to shut down any of the existing microservices (called pods in a Kubernetes cluster) at any time in order to free up resources or maintain the health of the application.

If the design of the application does not support graceful shutdowns, we could run into problems, such as the execution of a call to our application not being completed. That is why it is important to control shutdowns gracefully via the SIGTERM execution termination code.

When our application receives the termination code from SIGTERM execution, our application must close all the connections it has open at that moment and save any information that is useful for maintaining the current state prior to the end of execution.

In Kubernetes, this can be done with the preStop hook, which we will explore in Chapter 5, Virtual Machines and Container Applications on Google Cloud Platform.

But Kubernetes workloads are not the only case where we need to handle graceful shutdowns. For example, GCP has a GCE virtual machine type called a preemptible VM instance. A preemptible VM instance can be purchased with a discount of up to 80% as long as you accept that the instance will terminate after 24 hours.

In that case, you can handle a graceful shutdown using a shutdown script. This script will be executed right before a virtual machine instance is stopped or restarted, allowing instances to perform tasks such as syncing with other applications or exporting logs.

You can also use a shutdown script when you are using other GCP solutions, such as Managed Instance Groups (MIGs), in order to gracefully shut down your instances when the MIG performs a scale-out operation (deleting instances inside the group).

You have been reading a chapter from
Google Cloud Certified Professional Cloud Developer Exam Guide
Published in: Sep 2021
Publisher: Packt
ISBN-13: 9781800560994
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