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Architecting Google Cloud Solutions

You're reading from   Architecting Google Cloud Solutions Learn to design robust and future-proof solutions with Google Cloud technologies

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Product type Paperback
Published in Apr 2021
Publisher Packt
ISBN-13 9781800563308
Length 472 pages
Edition 1st Edition
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Author (1):
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Victor Dantas Victor Dantas
Author Profile Icon Victor Dantas
Victor Dantas
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Table of Contents (17) Chapters Close

Preface 1. Section 1: Introduction to Google Cloud
2. Chapter 1: An Introduction to Google Cloud for Architects FREE CHAPTER 3. Chapter 2: Mastering the Basics of Google Cloud 4. Section 2: Designing Great Solutions in Google Cloud
5. Chapter 3: Designing the Network 6. Chapter 4: Architecting Compute Infrastructure 7. Chapter 5: Architecting Storage and Data Infrastructure 8. Chapter 6: Configuring Services for Observability 9. Chapter 7: Designing for Security and Compliance 10. Section 3: Designing for the Modern Enterprise
11. Chapter 8: Approaching Big Data and Data Pipelines 12. Chapter 9: Jumping on the DevOps Bandwagon with Site Reliability Engineering (SRE) 13. Chapter 10: Re-Architecting with Microservices 14. Chapter 11: Applying Machine Learning and Artificial Intelligence 15. Chapter 12: Achieving Operational Excellence 16. Other Books You May Enjoy

Understanding the motivations and economics of cloud computing

At what point do we stop calling it just a data center, and start calling it the "cloud”? The National Institute of Standards and Technology (NIST) defines the following five essential traits that characterize cloud computing:

  • On-demand, self-service
  • Broad network access
  • Resource pooling
  • Rapid elasticity or expansion
  • Measured service

The ability to deliver elastic services that can scale to adapt to varying demand, while paying only for the resources that you use, is what makes cloud computing so appealing and powerful.

The main enabling technology is that of infrastructure virtualization (or cloudification, as it is sometimes referred to), which has been made possible in the past few decades by the commoditization of hardware and new paradigms such as software-defined networking (SDN), in which the system's "intelligence” (control plane) is decoupled from the system's underlying hardware processing functions (the data plane).

These new technologies have allowed for increased levels of programmability of the infrastructure, where provisioned infrastructure resources can be abstracted and services can be exposed through application programming interfaces (APIs), in the same way that software applications' resources are. For example, with a few REST API calls, you can deploy a virtual network environment with virtual machines and public IP addresses. This has made cloud computing much more accessible to professionals working in roles beyond those of traditional enterprise IT or solution architects. It has also facilitated the emergence of the Infrastructure-as-Code (IaC) paradigm and the DevOps culture.

It has done this by enabling infrastructure resources to be defined in text-based declarative language and source-controlled in a code repository, and deployments to be streamlined via pipelines. At the time of writing, there is nothing standing between a team of developers and a complete infrastructure ready to run application workloads at any scale, except perhaps the required budget for doing so.

The NIST definition also lists four cloud deployment models:

  • Private
  • Community
  • Public
  • Hybrid

These models relate to the ownership of the hosting infrastructure. This book is about Google Cloud, which is owned and operated by Google as the cloud service provider and delivered over the internet through the public cloud model. In a public cloud, the infrastructure resources are shared between organizations (or cloud "tenants”), which means that within the same physical hosting infrastructure, several different virtualized systems from different customers may be running alongside each other. This, along with the lack of control and visibility over the underlying physical infrastructure, is one of the most criticized aspects of the public cloud model since it raises security and privacy concerns. It is the reason some organizations are reluctant to seriously consider migrating their infrastructure to the public cloud, and also the reason several others settle "somewhere in the middle” with a hybrid cloud deployment, in which only part of their infrastructure is hosted in a public cloud environment (the remaining part being privately hosted).

What makes cloud computing so disruptive and appealing, however, is not solely the new technological model that's enabled by virtualization technologies and commodity hardware, but the economic model that ensues (at least for the players in the market with deep enough pockets), which is that of economies of scale and global reach. While IT systems are generally expensive to purchase and maintain, being able to buy resources in massive quantities and build several data centers across the globe enables you to reduce and amortize those costs greatly, and then pass those savings on to your customers, who themselves can benefit from the consumption-based model and avoid large upfront investments and commitments. It's a win-win situation.

This is the shift from Capital Expenditures (CAPEX) to Operational Expenditures (OPEX) that we hear about so often, and is one of the tenets of cloud computing.

CAPEX versus OPEX

Instead of purchasing your own expensive infrastructure with a large upfront investment (the CAPEX model), you can benefit from the pay-as-you-go pricing model offered in the public cloud as a monthly consumption fee with no termination penalty (the OPEX model). Pay-as-you-go simply means you pay only for the resources you consume, while you consume them, and it's a bundled price that includes everything from any potential software licenses down to maintenance costs of the physical infrastructure running the service. This is in contrast to acquiring your own private infrastructure (or private cloud), in which case you would size it for the expected maximum demand and commit with a large upfront investment to this full available capacity, even if you only utilize a fraction of that capacity most of the time.

For organizations whose line-of-business applications have varying demands based on, for example, day of the week or time of the year (indeed, this is the case for most web-based applications today), the ability to only pay for extra resource allocation only during the few hours or days that those extra resources are needed is very beneficial financially. Resource utilization efficiency is maximized. What is even better is that such scaling events can be done automatically, and they require no on-call operations personnel to handle them.

The shift from CAPEX to OPEX also has implications on cash flow. Rather than having to pay a large, upfront infrastructure cost (the price commitment for which may go beyond the budget of smaller organizations, which would force them to borrow money and deal with interest costs), organizations can smooth out cash flows over time and drive improved average margin per user. In addition, it offers a much lower financial "penalty” for start - ups that pivot their business in a way that would drive major changes in the infrastructure architecture (in other words, it costs less to "pull the plug” on infrastructure "purchase” decisions).

Technology enablement

Cloud technologies are also powering a new range of applications that require immense distributed computing power and AI capabilities. The possibility to scale compute needs on-demand and pay only for what you use means that many more companies can benefit from this powerful and virtually limitless capacity, as they don't need to rely on prohibitively expensive infrastructure of their own to support such high-demand workloads.

Google has invested heavily over the years in their infrastructure and machine learning models since services such as Google Search, Google Maps, and YouTube – some of the most powerful data-driven services at the highest scale you can think of today – run on the same infrastructure and use the same technologies that Google now makes available for Google Cloud customers for consumption.

The NIST definition for cloud computing also lists three "service models” that, together with the deployment models, characterize the ways services are delivered in the cloud:

  • Software-as-a-Service, also known as SaaS
  • Platform-as-a-Service, also known as PaaS
  • Infrastructure-as-a-Service, also known as IaaS

These relate to which layers of the infrastructure are managed and operated by the cloud provider (or the infrastructure owner) and which are your responsibility as a consumer.

In a public cloud, such as Google Cloud, the delivery models are easy to reason about when you're visualizing the stack of infrastructure layers against your – and the cloud provider's – responsibility for managing and operating each layer:

Figure 1.1 – Difference in management responsibilities (on-premises versus IaaS versus PaaS versus SaaS)

Figure 1.1 – Difference in management responsibilities (on-premises versus IaaS versus PaaS versus SaaS)

Organizations with a medium to large digital estate and several different types of workloads will typically acquire not one but a mix of services across different models, based on the specific requirements and technical constraints of each workload. For example, you may have a stateless application that you developed with a standard programming language and framework hosted on a PaaS service, while you may have another application in the same cloud environment that relies heavily on custom libraries and features, and is therefore hosted on a virtual machine (IaaS). As we will see throughout this book, there are several considerations and design trade-offs to take into account when choosing which delivery model is best, but typically, it comes down to a tug of war between control over the underlying platform (things such as patch and update schedules, the configurability of the application runtime and framework, access to the operating system's filesystem, custom VM images, and so on) and low management overhead (low to no platform operation, smaller and more independent application teams).

Cloud-native or cloud-first organizations will typically consume more of the PaaS and SaaS services, and rely less on IaaS VMs. This reduces dependencies on infrastructure teams and allows development-focused teams to quickly and easily deploy code to a platform whose infrastructure management is delegated to the cloud provider. This is one reason why the public cloud has a very strong appeal to smaller organizations and start - up software companies.

For other organizations, you may need to make a convincing case for the public cloud to get executive buy-in. Next, we'll explore how to make the business case for cloud adoption.

You have been reading a chapter from
Architecting Google Cloud Solutions
Published in: Apr 2021
Publisher: Packt
ISBN-13: 9781800563308
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