Hybrid and multicloud architecture patterns

Last reviewed 2023-12-14 UTC

This document is the second of three documents in a set. It discusses common hybrid and multicloud architecture patterns. It also describes the scenarios that these patterns are best suited for. Finally, it provides the best practices you can use when deploying such architectures in Google Cloud.

The document set for hybrid and multicloud architecture patterns consists of these parts:

Every enterprise has a unique portfolio of application workloads that place requirements and constraints on the architecture of a hybrid or multicloud setup. Although you must design and tailor your architecture to meet these constraints and requirements, you can rely on some common patterns to define the foundational architecture.

An architecture pattern is a repeatable way to structure multiple functional components of a technology solution, application, or service to create a reusable solution that addresses certain requirements or use cases. A cloud-based technology solution is often made of several distinct and distributed cloud services. These services collaborate to deliver required functionality. In this context, each service is considered a functional component of the technology solution. Similarly, an application can consist of multiple functional tiers, modules, or services, and each can represent a functional component of the application architecture. Such an architecture can be standardized to address specific business use cases and serve as a foundational, reusable pattern.

To generally define an architecture pattern for an application or solution, identify and define the following:

  • The components of the solution or application.
  • The expected functions for each component—for example, frontend functions to provide a graphical user interface or backend functions to provide data access.
  • How the components communicate with each other and with external systems or users. In modern applications, these components interact through well-defined interfaces or APIs. There are a wide range of communication models such as asynchronous and synchronous, request-response, or queue-based.

The following are the two main categories of hybrid and multicloud architecture patterns:

  • Distributed architecture patterns: These patterns rely on a distributed deployment of workloads or application components. That means they run an application (or specific components of that application) in the computing environment that suits the pattern best. Doing so lets the pattern capitalize on the different properties and characteristics of distributed and interconnected computing environments.
  • Redundant architecture patterns: These patterns are based on redundant deployments of workloads. In these patterns, you deploy the same applications and their components in multiple computing environments. The goal is to either increase the performance capacity or resiliency of an application, or to replicate an existing environment for development and testing.

When you implement the architecture pattern that you select, you must use a suitable deployment archetype. Deployment archetypes are zonal, regional, multi-regional, or global. This selection forms the basis for constructing application-specific deployment architectures. Each deployment archetype defines a combination of failure domains within which an application can operate. These failure domains can encompass one or more Google Cloud zones or regions, and can be expanded to include your on-premises data centers or failure domains in other cloud providers.

This series contains the following pages:

Contributors

Author: Marwan Al Shawi | Partner Customer Engineer

Other contributors:

Distributed architecture patterns

When migrating from a non-hybrid or non-multicloud computing environment to a hybrid or multicloud architecture, first consider the constraints of your existing applications and how those constraints could lead to application failure. This consideration becomes more important when your applications or application components operate in a distributed manner across different environments. After you have considered your constraints, develop a plan to avoid or overcome them. Make sure to consider the unique capabilities of each computing environment in a distributed architecture.

Design considerations

The following design considerations apply to distributed deployment patterns. Depending on the target solution and business objectives, the priority and the effect of each consideration can vary.

Latency

In any architecture pattern that distributes application components (frontends, backends, or microservices) across different computing environments, communication latency can occur. This latency is influenced by the hybrid network connectivity (Cloud VPN and Cloud Interconnect) and the geographical distance between the on-premises site and the cloud regions, or between cloud regions in a multicloud setup. Therefore, it's crucial to assess the latency requirements of your applications and their sensitivity to network delays. Applications that can tolerate latency are more suitable candidates for initial distributed deployment in a hybrid or multicloud environment.

Temporary versus final state architecture

To specify the expectations and any potential implications for cost, scale, and performance, it's important to analyze what type of architecture you need and the intended duration as part of the planning stage. For example, if you plan to use a hybrid or multicloud architecture for a long time or permanently, you might want to consider using Cloud Interconnect. To reduce outbound data transfer costs and to optimize hybrid connectivity network performance, Cloud Interconnect discounts the outbound data transfer charges that meet the discounted data transfer rate conditions.

Reliability

Reliability is a major consideration when architecting IT systems. Uptime availability is an essential aspect of system reliability. In Google Cloud, you can increase the resiliency of an application by deploying redundant components of that application across multiple zones in a single region, or across multiple regions, with switchover capabilities. Redundancy is one of the key elements to improve the overall availability of an application. For applications with a distributed setup across hybrid and multicloud environments, it's important to maintain a consistent level of availability.

To enhance the availability of a system in an on-premises environment, or in other cloud environments, consider what hardware or software redundancy—with failover mechanisms—you need for your applications and their components. Ideally, you should consider the availability of a service or an application across the various components and supporting infrastructure (including hybrid connectivity availability) across all the environments. This concept is also referred to as the composite availability of an application or service.

Based on the dependencies between the components or services, the composite availability for an application might be higher or lower than for an individual service or component. For more information, see Composite availability: calculating the overall availability of cloud infrastructure.

To achieve the level of system reliability that you want, define clear reliability metrics and design applications to self-heal and endure disruptions effectively across the different environments. To help you define appropriate ways to measure the customer experience of your services, see Define your reliability goals.

Hybrid and multicloud connectivity

The requirements of the communication between the distributed applications components should influence your selection of a hybrid network connectivity option. Each connectivity option has its advantages and disadvantages, as well as specific drivers to consider, such as cost, traffic volume, security, and so forth. For more information, see the connectivity design considerations section.

Manageability

Consistent and unified management and monitoring tools are essential for successful hybrid and multicloud setups (with or without workload portability). In the short term, these tools can add development, testing, and operations costs. Technically, the more cloud providers you use, the more complex managing your environments becomes. Most public cloud vendors not only have different features, but also have varying tools, SLAs, and APIs for managing cloud services. Therefore, weigh the strategic advantages of your selected architecture against the potential short-term complexity versus the long-term benefits.

Cost

Each cloud service provider in a multicloud environment has its own billing metrics and tools. To provide better visibility and unified dashboards, consider using multicloud cost management and optimization tooling. For example, when building cloud-first solutions across multiple cloud environments each provider's products, pricing, discounts, and management tools can create cost inconsistencies between those environments.

We recommend having a single, well-defined method for calculating the full costs of cloud resources, and to provide cost visibility. Cost visibility is essential for cost optimization. For example, by combining billing data from the cloud providers you use and using Google Cloud Looker Cloud Cost Management Block, you can create a centralized view of your multicloud costs. This view can help provide a consolidated reporting view of your spend across multiple clouds. For more information, see The strategy for effectively optimizing cloud billing cost management.

We also recommend using FinOps practice to make costs visible. As a part of a strong FinOps practice, a central team can delegate the decision making for resource optimization to any other teams involved in a project to encourage individual accountability. In this model, the central team should standardize the process, the reporting, and the tooling for cost optimization. For more information about the different cost optimization aspects and recommendations that you should consider, see Google Cloud Architecture Framework: Cost optimization.

Data movement

Data movement is an important consideration for hybrid and multicloud strategy and architecture planning, especially for distributed systems. Enterprises need to identify their different business use cases, the data that powers them, and how the data is classified (for regulated industries). They should also consider how data storage, sharing, and access for distributed systems across environments might affect application performance and data consistency. Those factors might influence the application and the data pipeline architecture. Google Cloud's comprehensive set of data movement options makes it possible for businesses to meet their specific needs and adopt hybrid and multicloud architectures without compromising simplicity, efficiency, or performance.

Security

When migrating applications to the cloud, it's important to consider cloud-first security capabilities like consistency, observability, and unified security visibility. Each public cloud provider has its own approach, best practices, and capabilities for security. It's important to analyze and align these capabilities to build a standard, functional security architecture. Strong IAM controls, data encryption, vulnerability scanning, and compliance with industry regulations are also important aspects of cloud security.

When planning a migration strategy, we recommend that you analyze the previously mentioned considerations. They can help you minimize the chances of introducing complexities to the architecture as your applications or traffic volumes grow. Also, designing and building a landing zone is almost always a prerequisite to deploying enterprise workloads in a cloud environment. A landing zone helps your enterprise deploy, use, and scale cloud services more securely across multiple areas and includes different elements, such as identities, resource management, security, and networking. For more information, see Landing zone design in Google Cloud.

The following documents in this series describe other distributed architecture patterns:

Tiered hybrid pattern

The architecture components of an application can be categorized as either frontend or backend. In some scenarios, these components can be hosted to operate from different computing environments. As part of the tiered hybrid architecture pattern, the computing environments are located in an on-premises private computing environment and in Google Cloud.

Frontend application components are directly exposed to end users or devices. As a result, these applications are often performance sensitive. To develop new features and improvements, software updates can be frequent. Because frontend applications usually rely on backend applications to store and manage data—and possibly business logic and user input processing—they're often stateless or manage only limited volumes of data.

To be accessible and usable, you can build your frontend applications with various frameworks and technologies. Some key factors for a successful frontend application include application performance, response speed, and browser compatibility.

Backend application components usually focus on storing and managing data. In some architectures, business logic might be incorporated within the backend component. New releases of backend applications tend to be less frequent than releases for frontend applications. Backend applications have the following challenges to manage:

  • Handling a large volume of requests
  • Handling a large volume of data
  • Securing data
  • Maintaining current and updated data across all the system replicas

The three-tier application architecture is one of the most popular implementations for building business web applications, like ecommerce websites containing different application components. This architecture contains the following tiers. Each tier operates independently, but they're closely linked and all function together.

  • Web frontend and presentation tier
  • Application tier
  • Data access or backend tier

Putting these layers into containers separates their technical needs, like scaling requirements, and helps to migrate them in a phased approach. Also, it lets you deploy them on platform-agnostic cloud services that can be portable across environments, use automated management, and scale with cloud managed platforms, like Cloud Run or Google Kubernetes Engine (GKE) Enterprise edition. Also, Google Cloud-managed databases like Cloud SQL help to provide the backend as the database layer.

The tiered hybrid architecture pattern focuses on deploying existing frontend application components to the public cloud. In this pattern, you keep any existing backend application components in their private computing environment. Depending on the scale and the specific design of the application, you can migrate frontend application components on a case-by-case basis. For more information, see Migrate to Google Cloud.

If you have an existing application with backend and frontend components hosted in your on-premises environment, consider the limits of your current architecture. For example, as your application scales and the demands on its performance and reliability increase, you should start evaluating whether parts of your application should be refactored or moved to a different and more optimal architecture. The tiered hybrid architecture pattern lets you shift some application workloads and components to the cloud before making a complete transition. It's also essential to consider the cost, time, and risk involved in such a migration.

The following diagram shows a typical tiered hybrid architecture pattern.

Data flow from an on-premises application frontend, to an application frontend in Google Cloud. Data then flows back to the on-premises environment.

In the preceding diagram, client requests are sent to the application frontend that is hosted in Google Cloud. In turn, the application frontend sends data back to the on-premises environment where the application backend is hosted (ideally through an API gateway).

With the tiered hybrid architecture pattern, you can take advantage of Google Cloud infrastructure and global services, as shown in the example architecture in the following diagram. The application frontend can be reached over Google Cloud. It can also add elasticity to the frontend by using auto-scaling to dynamically and efficiently respond to scaling demand without over provisioning infrastructure. There are different architectures that you can use to build and run scalable web apps on Google Cloud. Each architecture has advantages and disadvantages for different requirements.

For more information, watch Three ways to run scalable web apps on Google Cloud on YouTube. To learn more about different ways to modernize your ecommerce platform on Google Cloud, see How to build a digital commerce platform on Google Cloud.

Data flow from users to an on-premises database server through a Cloud Load Balancing and Compute Engine.

In the preceding diagram, the application frontend is hosted on Google Cloud to provide a multi-regional and globally optimized user experience that uses global load balancing, autoscaling, and DDoS protection through Google Cloud Armor.

Over time, the number of applications that you deploy to the public cloud might increase to the point where you might consider moving backend application components to the public cloud. If you expect to serve heavy traffic, opting for cloud-managed services might help you save engineering effort when managing your own infrastructure. Consider this option unless constraints or requirements mandate hosting backend application components on-premises. For example, if your backend data is subject to regulatory restrictions, you probably need to keep that data on-premises. Where applicable and compliant, however, using Sensitive Data Protection capabilities like de-identification techniques, can help you move that data when necessary.

In the tiered hybrid architecture pattern, you also can use Google Distributed Cloud in some scenarios. Distributed Cloud lets you run Google Kubernetes Engine clusters on dedicated hardware that's provided and maintained by Google and is separate from Google Cloud data center. To ensure that Distributed Cloud meets your current and future requirements, know the limitations of Distributed Cloud when compared to a conventional cloud-based GKE zone.

Advantages

Focusing on frontend applications first has several advantages including the following:

  • Frontend components depend on backend resources and occasionally on other frontend components.
  • Backend components don't depend on frontend components. Therefore, isolating and migrating frontend applications tends to be less complex than migrating backend applications.
  • Because frontend applications often are stateless or don't manage data by themselves, they tend to be less challenging to migrate than backends.

Deploying existing or newly developed frontend applications to the public cloud offers several advantages:

  • Many frontend applications are subject to frequent changes. Running these applications in the public cloud simplifies the setup of a continuous integration/continuous deployment (CI/CD) process. You can use CI/CD to send updates in an efficient and automated manner. For more information, see CI/CD on Google Cloud.
  • Performance-sensitive frontends with varying traffic load can benefit substantially from the load balancing, multi-regional deployments, Cloud CDN caching, serverless, and autoscaling capabilities that a cloud-based deployment enables (ideally with stateless architecture).
  • Adopting microservices with containers using a cloud-managed platform, like GKE, lets you use modern architectures like microfrontend, which extend microservices to the frontend components.

    Extending microservices is commonly used with frontends that involve multiple teams collaborating on the same application. That kind of team structure requires an iterative approach and continuous maintenance. Some of the advantages of using microfrontend are as follows:

    • It can be made into independent microservices modules for development, testing, and deployment.
    • It provides separation where individual development teams can select their preferred technologies and code.
    • It can foster rapid cycles of development and deployment without affecting the rest of the frontend components that might be managed by other teams.
  • Whether they're implementing user interfaces or APIs, or handling Internet of Things (IoT) data ingestion, frontend applications can benefit from the capabilities of cloud services like Firebase, Pub/Sub, Apigee, Cloud CDN, App Engine, or Cloud Run.

  • Cloud-managed API proxies help to:

    • Decouple the app-facing API from your backend services, like microservices.
    • Shield apps from backend code changes.
    • Support your existing API-driven frontend architectures, like backend for frontend (BFF), microfrontend, and others.
    • Expose your APIs on Google Cloud or other environments by implementing API proxies on Apigee.

You can also apply the tiered hybrid pattern in reverse, by deploying backends in the cloud while keeping frontends in private computing environments. Although it's less common, this approach is best applied when you're dealing with a heavyweight and monolithic frontend. In such cases, it might be easier to extract backend functionality iteratively, and to deploy these new backends in the cloud.

The third part of this series discusses possible networking patterns to enable such an architecture. Apigee hybrid helps as a platform for building and managing API proxies in a hybrid deployment model. For more information, see Loosely coupled architecture, including tiered monolithic and microservices architectures.

Best practices

Use the information in this section as you plan for your tiered hybrid architecture.

Best practices to reduce complexity

When you're applying the tiered hybrid architecture pattern, consider the following best practices that can help to reduce its overall deployment and operational complexity:

  • Based on the assessment of the communication models of the identified applications, select the most efficient and effective communication solution for those applications.

Because most user interaction involves systems that connect across multiple computing environments, fast and low-latency connectivity between those systems is important. To meet availability and performance expectations, you should design for high availability, low latency, and appropriate throughput levels. From a security point of view, communication needs to be fine-grained and controlled. Ideally, you should expose application components using secure APIs. For more information, see Gated egress.

  • To minimize communication latency between environments, select a Google Cloud region that is geographically close to the private computing environment where your application backend components are hosted. For more information, see Best practices for Compute Engine regions selection.
  • Minimize high dependencies between systems that are running in different environments, particularly when communication is handled synchronously. These dependencies can slow performance, decrease overall availability, and potentially incur additional outbound data transfer charges.
  • With the tiered hybrid architecture pattern, you might have larger volumes of inbound traffic from on-premises environments coming into Google Cloud compared to outbound traffic leaving Google Cloud. Nevertheless, you should know the anticipated outbound data transfer volume leaving Google Cloud. If you plan to use this architecture long term with high outbound data transfer volumes, consider using Cloud Interconnect. Cloud Interconnect can help to optimize connectivity performance and might reduce outbound data transfer charges for traffic that meets certain conditions. For more information, see Cloud Interconnect pricing.
  • To protect sensitive information, we recommend encrypting all communications in transit. If encryption is required at the connectivity layer, you can use VPN tunnels, HA VPN over Cloud Interconnect, and MACsec for Cloud Interconnect.
  • To overcome inconsistencies in protocols, APIs, and authentication mechanisms across diverse backends, we recommend, where applicable, to deploy an API gateway or proxy as a unifying facade. This gateway or proxy acts as a centralized control point and performs the following measures:

    • Implements additional security measures.
    • Shields client apps and other services from backend code changes.
    • Facilitates audit trails for communication between all cross-environment applications and its decoupled components.
    • Acts as an intermediate communication layer between legacy and modernized services.
      • Apigee and Apigee hybrid lets you host and manage enterprise-grade and hybrid gateways across on-premises environments, edge, other clouds, and Google Cloud environments.
  • To facilitate the establishment of hybrid setups, use Cloud Load Balancing with hybrid connectivity. That means you can extend the benefits of cloud load balancing to services hosted on your on-premises compute environment. This approach enables phased workload migrations to Google Cloud with minimal or no service disruption, ensuring a smooth transition for the distributed services. For more information, see Hybrid connectivity network endpoint groups overview.

  • Sometimes, using an API gateway, or a proxy and an Application Load Balancer together, can provide a more robust solution for managing, securing, and distributing API traffic at scale. Using Cloud Load Balancing with API gateways lets you accomplish the following:

  • Use API management and service mesh to secure and control service communication and exposure with microservices architecture.

    • Use Cloud Service Mesh to allow for service-to-service communication that maintains the quality of service in a system composed of distributed services where you can manage authentication, authorization, and encryption between services.
    • Use an API management platform like Apigee that lets your organization and external entities consume those services by exposing them as APIs.
  • Establish common identity between environments so that systems can authenticate securely across environment boundaries.

  • Deploy CI/CD and configuration management systems in the public cloud. For more information, see Mirrored networking architecture pattern.

  • To help increase operational efficiency, use consistent tooling and CI/CD pipelines across environments.

Best practices for individual workload and application architectures

  • Although the focus lies on frontend applications in this pattern, stay aware of the need to modernize your backend applications. If the development pace of backend applications is substantially slower than for frontend applications, the difference can cause extra complexity.
  • Treating APIs as backend interfaces streamlines integrations, frontend development, service interactions, and hides backend system complexities. To address these challenges, Apigee facilitates API gateway/proxy development and management for hybrid and multicloud deployments.
  • Choose the rendering approach for your frontend web application based on the content (static versus dynamic), the search engine optimization performance, and the expectations about page loading speeds.
  • When selecting an architecture for content-driven web applications, various options are available, including monolithic, serverless, event-based, and microservice architectures. To select the most suitable architecture, thoroughly assess these options against your current and future application requirements. To help you make an architectural decision that's aligned with your business and technical objectives, see Comparison of different architectures for content-driven web application backends, and Key Considerations for web backends.
  • With a microservices architecture, you can use containerized applications with Kubernetes as the common runtime layer. With the tiered hybrid architecture pattern, you can run it in either of the following scenarios:

    • Across both environments (Google Cloud and your on-premises environments).

      • When using containers and Kubernetes across environments, you have the flexibility to modernize workloads and then migrate to Google Cloud at different times. That helps when a workload depends heavily on another and can't be migrated individually, or to use hybrid workload portability to use the best resources available in each environment. In all cases, GKE Enterprise can be a key enabling technology. For more information, see GKE Enterprise hybrid environment.
    • In a Google Cloud environment for the migrated and modernized application components.

      • Use this approach when you have legacy backends on-premises that lack containerization support or require significant time and resources to modernize in the short-term.

      For more information about designing and refactoring a monolithic app to a microservice architecture to modernize your web application architecture, see Introduction to microservices.

  • You can combine data storage technologies depending on the needs of your web applications. Using Cloud SQL for structured data and Cloud Storage for media files is a common approach to meet diverse data storage needs. That said, the choice depends heavily on your use case. For more information about data storage options for content-driven application backends and effective modalities, see Data Storage Options for Content-Driven Web Apps. Also, see Your Google Cloud database options, explained

Partitioned multicloud pattern

The partitioned multicloud architecture pattern combines multiple public cloud environments that are operated by different cloud service providers. This architecture provides the flexibility to deploy an application in an optimal computing environment that accounts for the multicloud drivers and considerations discussed in the first part of this series.

The following diagram shows a partitioned multicloud architecture pattern.

Data flow from an application in Google Cloud to an application in a different cloud environment.

This architecture pattern can be built in two different ways. The first approach is based on deploying the application components in different public cloud environments. This approach is also referred to as a composite architecture and is the same approach as the tiered hybrid architecture pattern. Instead of using an on-premises environment with a public cloud, however, it uses at least two cloud environments. In a composite architecture, a single workload or application uses components from more than one cloud. The second approach deploys different applications on different public cloud environments. The following non-exhaustive list describes some of the business drivers for the second approach:

  • To fully integrate applications hosted in disparate cloud environments during a merger and acquisition scenario between two enterprises.
  • To promote flexibility and cater to diverse cloud preferences within your organization. Adopt this approach to encourage organizational units to choose the cloud provider that best suits their specific needs and preferences.
  • To operate in a multi-regional or global-cloud deployment. If an enterprise is required to adhere to data residency regulations in specific regions or countries, then they need to choose from among the available cloud providers in that location if their primary cloud provider does not have a cloud region there.

With the partitioned multicloud architecture pattern, you can optionally maintain the ability to shift workloads as needed from one public cloud environment to another. In that case, the portability of your workloads becomes a key requirement. When you deploy workloads to multiple computing environments, and want to maintain the ability to move workloads between environments, you must abstract away the differences between the environments. By using GKE Enterprise, you can design and build a solution to solve multicloud complexity with consistent governance, operations, and security postures. For more information, see GKE Multi-Cloud.

As previously mentioned, there are some situations where there might be both business and technical reasons to combine Google Cloud with another cloud provider and to partition workloads across those cloud environments. Multicloud solutions offer you the flexibility to migrate, build, and optimize applications portability across multicloud environments while minimizing lock-in, and helping you to meet your regulatory requirements. For example, you might connect Google Cloud with Oracle Cloud Infrastructure (OCI), to build a multicloud solution that harnesses the capabilities of each platform using a private Cloud Interconnect to combine components running in OCI with resources running on Google Cloud. For more information, see Google Cloud and Oracle Cloud Infrastructure – making the most of multicloud. In addition, Cross-Cloud Interconnect facilitates high-bandwidth dedicated connectivity between Google Cloud and other supported cloud service providers, enabling you to architect and build multicloud solutions to handle high inter-cloud traffic volume.

Advantages

While using a multicloud architecture offers several business and technical benefits, as discussed in Drivers, considerations, strategy, and approaches, it's essential to perform a detailed feasibility assessment of each potential benefit. Your assessment should carefully consider any associated direct or indirect challenges or potential roadblocks, and your ability to navigate them effectively. Also, consider that the long-term growth of your applications or services can introduce complexities that might outweigh the initial benefits.

Here are some key advantages of the partitioned multicloud architecture pattern:

  • In scenarios where you might need to minimize committing to a single cloud provider, you can distribute applications across multiple cloud providers. As a result, you could relatively reduce vendor lock-in with the ability to change plans (to some extent) across your cloud providers. Open Cloud helps to bring Google Cloud capabilities, like GKE Enterprise, to different physical locations. By extending Google Cloud capabilities on-premises, in multiple public clouds, and on the edge, it provides flexibility, agility, and drives transformation.

  • For regulatory reasons, you can serve a certain segment of your user base and data from a country where Google Cloud doesn't have a cloud region.

  • The partitioned multicloud architecture pattern can help to reduce latency and improve the overall quality of the user experience in locations where the primary cloud provider does not have a cloud region or a point of presence. This pattern is especially useful when using high-capacity and low latency multicloud connectivity, such as Cross-Cloud Interconnect and CDN Interconnect with a distributed CDN.

  • You can deploy applications across multiple cloud providers in a way that lets you choose among the best services that the other cloud providers offer.

  • The partitioned multicloud architecture pattern can help facilitate and accelerate merger and acquisition scenarios, where the applications and services of the two enterprises might be hosted in different public cloud environments.

Best practices

  • Start by deploying a non-mission-critical workload. This initial deployment in the secondary cloud can then serve as a pattern for future deployments or migrations. However, this approach probably isn't applicable in situations where the specific workload is legally or regulatorily required to reside in a specific cloud region, and the primary cloud provider doesn't have a region in the required territory.
  • Minimize dependencies between systems that are running in different public cloud environments, particularly when communication is handled synchronously. These dependencies can slow performance, decrease overall availability, and potentially incur additional outbound data transfer charges.
  • To abstract away the differences between environments, consider using containers and Kubernetes where supported by the applications and feasible.
  • Ensure that CI/CD pipelines and tooling for deployment and monitoring are consistent across cloud environments.
  • Select the optimal network architecture pattern that provides the most efficient and effective communication solution for the applications you're using.
  • To meet your availability and performance expectations, design for end-to-end high availability (HA), low latency, and appropriate throughput levels.
  • To protect sensitive information, we recommend encrypting all communications in transit.

    • If encryption is required at the connectivity layer, various options are available, based on the selected hybrid connectivity solution. These options include VPN tunnels, HA VPN over Cloud Interconnect, and MACsec for Cross-Cloud Interconnect.
  • If you're using multiple CDNs as part of your multicloud partitioned architecture pattern, and you're populating your other CDN with large data files from Google Cloud, consider using CDN Interconnect links between Google Cloud and supported providers to optimize this traffic and, potentially, its cost.

  • Extend your identity management solution between environments so that systems can authenticate securely across environment boundaries.

  • To effectively balance requests across Google Cloud and another cloud platform, you can use Cloud Load Balancing. For more information, see Routing traffic to an on-premises location or another cloud.

    • If the outbound data transfer volume from Google Cloud toward other environments is high, consider using Cross-Cloud Interconnect.
  • To overcome inconsistencies in protocols, APIs, and authentication mechanisms across diverse backends, we recommend, where applicable, to deploy an API gateway or proxy as a unifying facade. This gateway or proxy acts as a centralized control point and performs the following measures:

    • Implements additional security measures.
    • Shields client apps and other services from backend code changes.
    • Facilitates audit trails for communication between all cross-environment applications and its decoupled components.
    • Acts as an intermediate communication layer between legacy and modernized services.
      • Apigee and Apigee hybrid lets you host and manage enterprise-grade and hybrid gateways across on-premises environments, edge, other clouds, and Google Cloud environments.
  • In some of the following cases, using Cloud Load Balancing with an API gateway can provide a robust and secure solution for managing, securing, and distributing API traffic at scale across multiple regions:

    • Deploying multi-region failover for Apigee API runtimes in different regions.
    • Increasing performance with Cloud CDN.

    • Providing WAF and DDoS protection through Google Cloud Armor.

  • Use consistent tools for logging and monitoring across cloud environments where possible. You might consider using open source monitoring systems. For more information, see Hybrid and multicloud monitoring and logging patterns.

  • If you're deploying application components in a distributed manner where the components of a single application are deployed in more than one cloud environment, see the best practices for the tiered hybrid architecture pattern.

Analytics hybrid and multicloud pattern

This document discusses that the objective of the analytics hybrid and multicloud pattern is to capitalize on the split between transactional and analytics workloads.

In enterprise systems, most workloads fall into these categories:

  • Transactional workloads include interactive applications like sales, financial processing, enterprise resource planning, or communication.
  • Analytics workloads include applications that transform, analyze, refine, or visualize data to aid decision-making processes.

Analytics systems obtain their data from transactional systems by either querying APIs or accessing databases. In most enterprises, analytics and transactional systems tend to be separate and loosely coupled. The objective of the analytics hybrid and multicloud pattern is to capitalize on this pre-existing split by running transactional and analytics workloads in two different computing environments. Raw data is first extracted from workloads that are running in the private computing environment and then loaded into Google Cloud, where it's used for analytical processing. Some of the results might then be fed back to transactional systems.

The following diagram illustrates conceptually possible architectures by showing potential data pipelines. Each path/arrow represents a possible data movement and transformation pipeline option that can be based on ETL or ELT, depending on the available data quality and targeted use case.

To move your data into Google Cloud and unlock value from it, use data movement services, a complete suite of data ingestion, integration, and replication services.

Data flowing from an on-premises or other cloud environment into Google Cloud, through ingest, pipelines, storage, analytics, into the application and presentation layer.

As shown in the preceding diagram, connecting Google Cloud with on-premises environments and other cloud environments can enable various data analytics use cases, such as data streaming and database backups. To power the foundational transport of a hybrid and multicloud analytics pattern that requires a high volume of data transfer, Cloud Interconnect and Cross-Cloud Interconnect provide dedicated connectivity to on-premises and other cloud providers.

Advantages

Running analytics workloads in the cloud has several key advantages:

  • Inbound traffic—moving data from your private computing environment or other clouds to Google Cloud—might be free of charge.
  • Analytics workloads often need to process substantial amounts of data and can be bursty, so they're especially well suited to being deployed in a public cloud environment. By dynamically scaling compute resources, you can quickly process large datasets while avoiding upfront investments or having to overprovision computing equipment.
  • Google Cloud provides a rich set of services to manage data throughout its entire lifecycle, ranging from initial acquisition through processing and analyzing to final visualization.
    • Data movement services on Google Cloud provide a complete suite of products to move, integrate, and transform data seamlessly in different ways.
    • Cloud Storage is well suited for building a data lake.
  • Google Cloud helps you to modernize and optimize your data platform to break down data silos. Using a data lakehouse helps to standardize across different storage formats. It can also provide the flexibility, scalability, and agility needed to help ensure that your data generates value for your business, rather than inefficiencies. For more information, see BigLake.

  • BigQuery Omni, provides compute power that runs locally to the storage on AWS or Azure. It also helps you query your own data stored in Amazon Simple Storage Service (Amazon S3) or Azure Blob Storage. This multicloud analytics capability lets data teams break down data silos. For more information about querying data stored outside of BigQuery, see Introduction to external data sources.

Best practices

To implement the analytics hybrid and multicloud architecture pattern, consider the following general best practices:

  • Use the handover networking pattern to enable the ingestion of data. If analytical results need to be fed back to transactional systems, you might combine both the handover and the gated egress pattern.
  • Use Pub/Sub queues or Cloud Storage buckets to hand over data to Google Cloud from transactional systems that are running in your private computing environment. These queues or buckets can then serve as sources for data-processing pipelines and workloads.
  • To deploy ETL and ELT data pipelines, consider using Cloud Data Fusion or Dataflow depending on your specific use case requirements. Both are fully managed, cloud-first data processing services for building and managing data pipelines.
  • To discover, classify, and protect your valuable data assets, consider using Google Cloud Sensitive Data Protection capabilities, like de-identification techniques. These techniques let you mask, encrypt, and replace sensitive data—like personally identifiable information (PII)—using a randomly generated or pre-determined key, where applicable and compliant.
  • When you have existing Hadoop or Spark workloads, consider migrating jobs to Dataproc and migrating existing HDFS data to Cloud Storage.
  • When you're performing an initial data transfer from your private computing environment to Google Cloud, choose the transfer approach that is best suited for your dataset size and available bandwidth. For more information, see Migration to Google Cloud: Transferring your large datasets.

  • If data transfer or exchange between Google Cloud and other clouds is required for the long term with high traffic volume, you should evaluate using Google Cloud Cross-Cloud Interconnect to help you establish high-bandwidth dedicated connectivity between Google Cloud and other cloud service providers (available in certain locations).

  • If encryption is required at the connectivity layer, various options are available based on the selected hybrid connectivity solution. These options include VPN tunnels, HA VPN over Cloud Interconnect, and MACsec for Cross-Cloud Interconnect.

  • Use consistent tooling and processes across environments. In an analytics hybrid scenario, this practice can help increase operational efficiency, although it's not a prerequisite.

Edge hybrid pattern

Running workloads in the cloud requires that clients in some scenarios have fast and reliable internet connectivity. Given today's networks, this requirement rarely poses a challenge for cloud adoption. There are, however, scenarios when you can't rely on continuous connectivity, such as:

  • Sea-going vessels and other vehicles might be connected only intermittently or have access only to high-latency satellite links.
  • Factories or power plants might be connected to the internet. These facilities might have reliability requirements that exceed the availability claims of their internet provider.
  • Retail stores and supermarkets might be connected only occasionally or use links that don't provide the necessary reliability or throughput to handle business-critical transactions.

The edge hybrid architecture pattern addresses these challenges by running time- and business-critical workloads locally, at the edge of the network, while using the cloud for all other kinds of workloads. In an edge hybrid architecture, the internet link is a noncritical component that is used for management purposes and to synchronize or upload data, often asynchronously, but isn't involved in time or business-critical transactions.

Data flowing from a Google Cloud environment to the edge.

Advantages

Running certain workloads at the edge and other workloads in the cloud offers several advantages:

  • Inbound traffic—moving data from the edge to Google Cloud—might be free of charge.
  • Running workloads that are business- and time-critical at the edge helps ensure low latency and self-sufficiency. If internet connectivity fails or is temporarily unavailable, you can still run all important transactions. At the same time, you can benefit from using the cloud for a significant portion of your overall workload.
  • You can reuse existing investments in computing and storage equipment.
  • Over time, you can incrementally reduce the fraction of workloads that are run at the edge and move them to the cloud, either by reworking certain applications or by equipping some edge locations with internet links that are more reliable.
  • Internet of Things (IoT)-related projects can become more cost-efficient by performing data computations locally. This allows enterprises to run and process some services locally at the edge, closer to the data sources. It also allows enterprises to selectively send data to the cloud, which can help to reduce the capacity, data transfer, processing, and overall costs of the IoT solution.
  • Edge computing can act as an intermediate communication layer between legacy and modernized services. For example, services that might be running a containerized API gateway such as Apigee hybrid). This enables legacy applications and systems to integrate with modernized services, like IoT solutions.

Best practices

Consider the following recommendations when implementing the edge hybrid architecture pattern:

  • If communication is unidirectional, use the gated ingress pattern.
  • If communication is bidirectional, consider the gated egress and gated ingress pattern.
  • If the solution consists of many edge remote sites connecting to Google Cloud over the public internet, you can use a software-defined WAN (SD-WAN) solution. You can also use Network Connectivity Center with a third-party SD-WAN router supported by a Google Cloud partner to simplify the provisioning and management of secure connectivity at scale.
  • Minimize dependencies between systems that are running at the edge and systems that are running in the cloud environment. Each dependency can undermine the reliability and latency advantages of an edge hybrid setup.
  • To manage and operate multiple edge locations efficiently, you should have a centralized management plane and monitoring solution in the cloud.
  • Ensure that CI/CD pipelines along with tooling for deployment and monitoring are consistent across cloud and edge environments.
  • Consider using containers and Kubernetes when applicable and feasible, to abstract away differences among various edge locations and also among edge locations and the cloud. Because Kubernetes provides a common runtime layer, you can develop, run, and operate workloads consistently across computing environments. You can also move workloads between the edge and the cloud.
    • To simplify the hybrid setup and operation, you can use GKE Enterprise for this architecture (if containers are used across the environments). Consider the possible connectivity options that you have to connect a GKE Enterprise cluster running in your on-premises or edge environment to Google Cloud.
  • As part of this pattern, although some GKE Enterprise components might sustain during a temporary connectivity interruption to Google Cloud, don't use GKE Enterprises when it's disconnected from Google Cloud as a nominal working mode. For more information, see Impact of temporary disconnection from Google Cloud.
  • To overcome inconsistencies in protocols, APIs, and authentication mechanisms across diverse backend and edge services, we recommend, where applicable, to deploy an API gateway or proxy as a unifying facade. This gateway or proxy acts as a centralized control point and performs the following measures:
    • Implements additional security measures.
    • Shields client apps and other services from backend code changes.
    • Facilitates audit trails for communication between all cross-environment applications and its decoupled components.
    • Acts as an intermediate communication layer between legacy and modernized services.
      • Apigee and Apigee Hybrid let you host and manage enterprise-grade and hybrid gateways across on-premises environments, edge, other clouds, and Google Cloud environments.
  • Establish common identity between environments so that systems can authenticate securely across environment boundaries.
  • Because the data that is exchanged between environments might be sensitive, ensure that all communication is encrypted in transit by using VPN tunnels, TLS, or both.

Environment hybrid pattern

With the environment hybrid architecture pattern, you keep the production environment of a workload in the existing data center. You then use the public cloud for your development and testing environments, or other environments. This pattern relies on the redundant deployment of the same applications across multiple computing environments. The goal of the deployment is to help increase capacity, agility, and resiliency.

When assessing which workloads to migrate, you might notice cases when running a specific application in the public cloud presents challenges:

  • Jurisdictional or regulatory constraints might require that you keep data in a specific country.
  • Third-party licensing terms might prevent you from operating certain software in a cloud environment.
  • An application might require access to hardware devices that are available only locally.

In such cases, consider not only the production environment but all environments that are involved in the lifecycle of an application, including development, testing, and staging systems. These restrictions often apply to the production environment and its data. They might not apply to other environments that don't use the actual data. Check with the compliance department of your organization or the equivalent team.

The following diagram shows a typical environment hybrid architecture pattern:

Data flowing from a development environment hosted in Google Cloud to a production environment located on-premises or in another cloud environment.

Running development and test systems in different environments than your production systems might seem risky and could deviate from your existing best practices or from your attempts to minimize differences between your environments. While such concerns are justified, they don't apply if you distinguish between the stages of the development and testing processes:

Although development, testing, and deployment processes differ for each application, they usually involve variations of the following stages:

  • Development: Creating a release candidate.
  • Functional testing or user acceptance testing: Verifying that the release candidate meets functional requirements.
  • Performance and reliability testing: Verifying that the release candidate meets nonfunctional requirements. It's also known as load testing.
  • Staging or deployment testing: Verifying that the deployment procedure works.
  • Production: Releasing new or updated applications.

Performing more than one of these stages in a single environment is rarely practical, so each stage usually requires one or more dedicated environments.

The primary purpose of a testing environment is to run functional tests. The primary purpose of a staging environment is to test if your application deployment procedures work as intended. By the time a release reaches a staging environment, your functional testing should be complete. Staging is the last step before you deploy software to your production deployment.

To ensure that test results are meaningful and that they apply to the production deployment, the set of environments that you use throughout an application's lifecycle must satisfy the following rules, to the extent possible:

  • All environments are functionally equivalent. That is, the architecture, APIs, and versions of operating systems and libraries are equivalent, and systems behave the same across environments. This equivalence avoids situations where applications work in one environment but fail in another, or where defects aren't reproducible.
  • Environments that are used for performance and reliability testing, staging, and production are non-functionally equivalent. That is, their performance, scale, and configuration, and the way they're operated and maintained, are either the same or differ only in insignificant ways. Otherwise, performance and staging tests become meaningless.

In general, it's fine if the environments that are used for development and functional testing differ non-functionally from the other environments.

As illustrated in the following diagram, the test and development environments are built on Google Cloud. A managed database, like Cloud SQL, can be used as an option for development and testing in Google Cloud. Development and testing can use the same database engine and version in the on-premises environment, one that's functionally equivalent, or a new version that's rolled out to the production environment after the testing stage. However, because the underlying infrastructure of the two environments aren't identical, this approach to performance load testing isn't valid.

Development and QA teams send data through Google Cloud test and QA instances to an invalid on-premises production system.

The following scenarios can fit well with the environment hybrid pattern:

  • Achieve functional equivalence across all environments by relying on Kubernetes as a common runtime layer where applicable and feasible. Google Kubernetes Engine (GKE) Enterprise edition can be a key enabling technology for this approach.
    • Ensure workload portability and abstract away differences between computing environments. With a zero trust service mesh, you can control and maintain the required communication separation between the different environments.
  • Run development and functional testing environments in the public cloud. These environments can be functionally equivalent to the remaining environments but might differ in nonfunctional aspects, like performance. This concept is illustrated in the preceding diagram.
  • Run environments for production, staging, and performance (load testing) and reliability testing in the private computing environment, ensuring functional and nonfunctional equivalence.

Design Considerations

  • Business needs: Each deployment and release strategy for applications has its own advantages and disadvantages. To ensure that the approach that you select aligns with your specific requirements, base your selections on a thorough assessment of your business needs and constraints.
  • Environment differences: As part of this pattern, the main goal of using this cloud environment is for development and testing. The final state is to host the tested application in the private on-premises environment (production). To avoid developing and testing a capability that might function as expected in the cloud environment and fail in the production environment (on-premises), the technical team must know and understand the architectures and capabilities of both environments. This includes dependencies on other applications and on the hardware infrastructure—for example, security systems that perform traffic inspection.
  • Governance: To control what your company is allowed to develop in the cloud and what data they can use for testing, use an approval and governance process. This process can also help your company make sure that it doesn't use any cloud features in your development and testing environments that don't exist in your on-premises production environment.
  • Success criteria: There must be clear, predefined, and measurable testing success criteria that align with the software quality assurance standards for your organization. Apply these standards to any application that you develop and test.
  • Redundancy: Although development and testing environments might not require as much reliability as the production environment, they still need redundant capabilities and the ability to test different failure scenarios. Your failure-scenario requirements might drive the design to include redundancy as part of your development and testing environment.

Advantages

Running development and functional testing workloads in the public cloud has several advantages:

  • You can automatically start and stop environments as the need arises. For example, you can provision an entire environment for each commit or pull request, allow tests to run, and then turn it off again. This approach also offers the following advantages:
    • You can reduce costs by stopping virtual machine (VM) instances when they're inactive, or by provisioning environments only on demand.
    • You can speed up development and testing by starting ephemeral environments for each pull-request. Doing so also reduces maintenance overhead and reduces inconsistencies in the build environment.
  • Running these environments in the public cloud helps build familiarity and confidence in the cloud and related tools, which might help with migrating other workloads. This approach is particularly helpful if you decide to explore Workload portability using containers and Kubernetes—for example, using GKE Enterprise across environments.

Best practices

To implement the environment hybrid architecture pattern successfully, consider the following recommendations:

  • Define your application communication requirements, including the optimal network and security design. Then, use the mirrored network pattern to help you design your network architecture to prevent direct communications between systems from different environments. If communication is required across environments, it has to be in a controlled manner.
  • The application deployment and testing strategy you choose should align with your business objectives and requirements. This might involve rolling out changes without downtime or implementing features gradually to a specific environment or user group before wider release.

  • To make workloads portable and to abstract away differences between environments, you might use containers with Kubernetes. For more information, see GKE Enterprise hybrid environment reference architecture.

  • Establish a common tool chain that works across computing environments for deploying, configuring, and operating workloads. Using Kubernetes gives you this consistency.

  • Ensure that CI/CD pipelines are consistent across computing environments, and that the exact same set of binaries, packages, or containers is deployed across those environments.

  • When using Kubernetes, use a CI system such as Tekton to implement a deployment pipeline that deploys to clusters and works across environments. For more information, see DevOps solutions on Google Cloud.

  • To help you with the continuous release of secure and reliable applications, incorporate security as an integral part of the DevOps process (DevSecOps). For more information, see Deliver and secure your internet-facing application in less than an hour using Dev(Sec)Ops Toolkit.

  • Use the same tools for logging and monitoring across Google Cloud and existing cloud environments. Consider using open source monitoring systems. For more information, see Hybrid and multicloud monitoring and logging patterns.

  • If different teams manage test and production workloads, using separate tooling might be acceptable. However, using the same tools with different view permissions can help reduce your training effort and complexity.

  • When you choose database, storage, and messaging services for functional testing, use products that have a managed equivalent on Google Cloud. Relying on managed services helps decrease the administrative effort of maintaining development and testing environments.

  • To protect sensitive information, we recommend encrypting all communications in transit. If encryption is required at the connectivity layer, various options are available that are based on the selected hybrid connectivity solution. These options include VPN tunnels, HA VPN over Cloud Interconnect, and MACsec for Cloud Interconnect.

The following table shows which Google Cloud products are compatible with common OSS products.

OSS product Compatible with Google Cloud product
Apache HBase Bigtable
Apache Beam Dataflow
CDAP Cloud Data Fusion
Apache Hadoop Dataproc
MySQL, PostgreSQL Cloud SQL
Redis Cluster, Redis, Memcached Memorystore
Network File System (NFS) Filestore
JMS, Kafka Pub/Sub
Kubernetes GKE Enterprise

Business continuity hybrid and multicloud patterns

The main driver of considering business continuity for mission-critical systems is to help an organization to be resilient and continue its business operations during and following failure events. By replicating systems and data over multiple geographical regions and avoiding single points of failure, you can minimize the risks of a natural disaster that affects local infrastructure. Other failure scenarios include severe system failure, a cybersecurity attack, or even a system configuration error.

Optimizing a system to withstand failures is essential for establishing effective business continuity. System reliability can be influenced by several factors, including, but not limited to, performance, resilience, uptime availability, security, and user experience. For more information on how to architect and operate reliable services on Google Cloud, see the reliability pillar of the Google Cloud Architecture Framework and building blocks of reliability in Google Cloud.

This architecture pattern relies on a redundant deployment of applications across multiple computing environments. In this pattern, you deploy the same applications in multiple computing environments with the aim of increasing reliability. Business continuity can be defined as the ability of an organization to continue its key business functions or services at predefined acceptable levels following a disruptive event.

Disaster recovery (DR) is considered a subset of business continuity, explicitly focusing on ensuring that the IT systems that support critical business functions are operational as soon as possible after a disruption. In general, DR strategies and plans often help form a broader business continuity strategy. From a technology point of view, when you start creating disaster recovery strategies, your business impact analysis should define two key metrics: the recovery point objective (RPO) and the recovery time objective (RTO). For more guidance on using Google Cloud to address disaster recovery, see the Disaster recovery planning guide.

The smaller the RPO and RTO target values are, the faster services might recover from an interruption with minimal data loss. However, this implies higher cost because it means building redundant systems. Redundant systems that are capable of performing near real-time data replication and that operate at the same scale following a failure event, increase complexity, administrative overhead, and cost.

The decision to select a DR strategy or pattern should be driven by a business impact analysis. For example, the financial losses incurred from even a few minutes of downtime for a financial services organization might far exceed the cost of implementing a DR system. However, businesses in other industries might sustain hours of downtime without a significant business effect.

When you run mission-critical systems in an on-premises data center, one DR approach is to maintain standby systems in a second data center in a different region. A more cost-effective approach, however, is to use a public cloud–based computing environment for failover purposes. This approach is the main driver of the business continuity hybrid pattern. The cloud can be especially appealing from a cost point of view, because it lets you turn off some of your DR infrastructure when it's not in use. To achieve a lower cost DR solution, a cloud solution lets a business accept the potential increase in RPO and RTO values.

Data flowing from an on-premises environment to a disaster recovery instance hosted in Google Cloud.

The preceding diagram illustrates the use of the cloud as a failover or disaster recovery environment to an on-premises environment.

A less common (and rarely required) variant of this pattern is the business continuity multicloud pattern. In that pattern, the production environment uses one cloud provider and the DR environment uses another cloud provider. By deploying copies of workloads across multiple cloud providers, you might increase availability beyond what a multi-region deployment offers.

Evaluating a DR across multiple clouds versus using one cloud provider with different regions requires a thorough analysis of several considerations, including the following:

  • Manageability
  • Security
  • Overall feasibility.
  • Cost
    • The potential outbound data transfer charges from more than one cloud provider could be costly with continuous inter-cloud communication.
    • There can be a high volume of traffic when replicating databases.
    • TCO and the cost of managing inter-cloud network infrastructure.

If your data needs to stay in your country to meet regulatory requirements, using a second cloud provider that's also in your country as a DR can be an option. That use of a second cloud provider assumes that there's no option to use an on-premises environment to build a hybrid setup. To avoid rearchitecting your cloud solution, ideally your second cloud provider should offer all the required capabilities and services you need in-region.

Design considerations

  • DR expectation: The RPO and the RTO targets your business wants to achieve should drive your DR architecture and build planning.
  • Solution architecture: With this pattern, you need to replicate the existing functions and capabilities of your on-premises environment to meet your DR expectations. Therefore, you need to assess the feasibility and viability of rehosting, refactoring, or rearchitecting your applications to provide the same (or more optimized) functions and performance in the cloud environment.
  • Design and build: Building a landing zone is almost always a prerequisite to deploying enterprise workloads in a cloud environment. For more information, see Landing zone design in Google Cloud.
  • DR invocation: It's important for your DR design and process to consider the following questions:

    • What triggers a DR scenario? For example, a DR might be triggered by the failure of specific functions or systems in the primary site.
    • How is the failover to the DR environment invoked? Is it a manual approval process, or can it be automated to achieve a low RTO target?
    • How should system failure detection and notification mechanisms be designed to invoke failover in alignment with the expected RTO?
    • How is traffic rerouted to the DR environment after the failure is detected?

    Validate your answers to these questions through testing.

  • Testing: Thoroughly test and evaluate the failover to DR. Ensure that it meets your RPO and RTO expectations. Doing so could give you more confidence to invoke DR when required. Any time a new change or update is made to the process or technology solution, conduct the tests again.

  • Team skills: One or more technical teams must have the skills and expertise to build, operate, and troubleshoot the production workload in the cloud environment, unless your environment is managed by a third party.

Advantages

Using Google Cloud for business continuity offers several advantages:

  • Because Google Cloud has many regions across the globe to choose from, you can use it to back up or replicate data to a different site within the same continent. You can also back up or replicate data to a site on a different continent.
  • Google Cloud offers the ability to store data in Cloud Storage in a dual-region or multi-region bucket. Data is stored redundantly in at least two separate geographic regions. Data stored in dual-region and multi-region buckets are replicated across geographic regions using default replication.
    • Dual-region buckets provide geo-redundancy to support business continuity and DR plans. Also, to replicate faster, with a lower RPO, objects stored in dual-regions can optionally use turbo replication across those regions.
    • Similarly multi-region replication provides redundancy across multiple regions, by storing your data within the geographic boundary of the multi-region.
  • Provides one or more of the following options to reduce capital expenses and operating expenses to build a DR:
    • Stopped VM instances only incur storage costs and are substantially cheaper than running VM instances. That means you can minimize the cost of maintaining cold standby systems.
    • The pay-per-use model of Google Cloud means that you only pay for the storage and compute capacity that you actually use.
    • Elasticity capabilities, like autoscaling, let you automatically scale or shrink your DR environment as needed.

For example, the following diagram shows an application running in an on-premises environment (production) that uses recovery components on Google Cloud with Compute Engine, Cloud SQL, and Cloud Load Balancing. In this scenario, the database is pre-provisioned using a VM-based database or using a Google Cloud managed database, like Cloud SQL, for faster recovery with continuous data replication. You can launch Compute Engine VMs from pre-created snapshots to reduce cost during normal operations. With this setup, and following a failure event, DNS needs to point to the Cloud Load Balancing external IP address.

An application running in an on-premises production environment using recovery components on Google Cloud with Compute Engine, Cloud SQL, and Cloud Load Balancing.

To have the application operational in the cloud, you need to provision the web and application VMs. Depending on the targeted RTO level and company policies, the entire process to invoke a DR, provision the workload in the cloud, and reroute the traffic, can be completed manually or automatically.

To speed up and automate the provisioning of the infrastructure, consider managing the infrastructure as code. You can use Cloud Build, which is a continuous integration service, to automatically apply Terraform manifests to your environment. For more information, see Managing infrastructure as code with Terraform, Cloud Build, and GitOps.

Best practices

When you're using the business continuity pattern, consider the following best practices:

  • Create a disaster recovery plan that documents your infrastructure along with failover and recovery procedures.
  • Consider the following actions based on your business impact analysis and the identified required RPO and RTO targets:
    • Decide whether backing up data to Google Cloud is sufficient, or whether you need to consider another DR strategy (cold, warm, or hot standby systems).
    • Define the services and products that you can use as building blocks for your DR plan.
    • Frame the applicable DR scenarios for your applications and data as part of your selected DR strategy.
  • Consider using the handover pattern when you're only backing up data. Otherwise, the meshed pattern might be a good option to replicate the existing environment network architecture.
  • Minimize dependencies between systems that are running in different environments, particularly when communication is handled synchronously. These dependencies can slow performance and decrease overall availability.
  • Avoid the spilt-brain problem. If you replicate data bidirectionally across environments, you might be exposed to the split-brain problem. The split-brain problem occurs when two environments that replicate data bidirectionally lose communication with each other. This split can cause systems in both environments to conclude that the other environment is unavailable and that they have exclusive access to the data. This can lead to conflicting modifications of the data. There are two common ways to avoid the split-brain problem:

    • Use a third computing environment. This environment allows systems to check for a quorum before modifying data.
    • Allow conflicting data modifications to be reconciled after connectivity is restored.

      With SQL databases, you can avoid the split-brain problem by making the original primary instance inaccessible before clients start using the new primary instance. For more information, see Cloud SQL database disaster recovery.

  • Ensure that CI/CD systems and artifact repositories don't become a single point of failure. When one environment is unavailable, you must still be able to deploy new releases or apply configuration changes.

  • Make all workloads portable when using standby systems. All workloads should be portable (where supported by the applications and feasible) so that systems remain consistent across environments. You can achieve this approach by considering containers and Kubernetes. By using Google Kubernetes Engine (GKE) Enterprise edition, you can simplify the build and operations.

  • Integrate the deployment of standby systems into your CI/CD pipeline. This integration helps ensure that application versions and configurations are consistent across environments.

  • Ensure that DNS changes are propagated quickly by configuring your DNS with a reasonably short time to live value so that you can reroute users to standby systems when a disaster occurs.

  • Select the DNS policy and routing policy that align with your architecture and solution behavior. Also, you can combine multiple regional load balancers with DNS routing policies to create global load-balancing architectures for different use cases, including hybrid setup.

  • Use multiple DNS providers. When using multiple DNS providers, you can:

    • Improve the availability and resiliency of your applications and services.
    • Simplify the deployment or migration of hybrid applications that have dependencies across on-premises and cloud environments with a multi-provider DNS configuration.

      Google Cloud offers an open source solution based on octoDNS to help you set up and operate an environment with multiple DNS providers. For more information, see Multi-provider public DNS using Cloud DNS.

  • Use load balancers when using standby systems to create an automatic failover. Keep in mind that load balancer hardware can fail.

  • Use Cloud Load Balancing instead of hardware load balancers to power some scenarios that occur when using this architecture pattern. Internal client requests or external client requests can be redirected to the primary environment or the DR environment based on different metrics, such as weight-based traffic splitting. For more information, see Traffic management overview for global external Application Load Balancer.

  • Consider using Cloud Interconnect or Cross-Cloud Interconnect if the outbound data transfer volume from Google Cloud toward the other environment is high. Cloud Interconnect can help to optimize the connectivity performance and might reduce outbound data transfer charges for traffic that meets certain conditions. For more information, see Cloud Interconnect pricing.

  • Consider using your preferred partner solution on Google Cloud Marketplace to help facilitate the data backups, replications, and other tasks that meet your requirements, including your RPO and RTO targets.

  • Test and evaluate DR invocation scenarios to understand how readily the application can recover from a disaster event when compared to the target RTO value.

  • Encrypt communications in transit. To protect sensitive information, we recommend encrypting all communications in transit. If encryption is required at the connectivity layer, various options are available based on the selected hybrid connectivity solution. These options include VPN tunnels, HA VPN over Cloud Interconnect, and MACsec for Cloud Interconnect.

Cloud bursting pattern

Internet applications can experience extreme fluctuations in usage. While most enterprise applications don't face this challenge, many enterprises must deal with a different kind of bursty workload: batch or CI/CD jobs.

This architecture pattern relies on a redundant deployment of applications across multiple computing environments. The goal is to increase capacity, resiliency, or both.

While you can accommodate bursty workloads in a data-center-based computing environment by overprovisioning resources, this approach might not be cost effective. With batch jobs, you can optimize use by stretching their execution over longer time periods, although delaying jobs isn't practical if they're time sensitive.

The idea of the cloud bursting pattern is to use a private computing environment for the baseline load and burst to the cloud temporarily when you need extra capacity.

Data flowing from an on-premises environment to Google Cloud in burst mode.

In the preceding diagram, when data capacity is at its limit in an on-premises private environment, the system can gain extra capacity from a Google Cloud environment when needed.

The key drivers of this pattern are saving money and reducing the time and effort needed to respond to scale requirement changes. With this approach, you only pay for the resources used when handling extra loads. That means you don't need to overprovision your infrastructure. Instead you can take advantage of on-demand cloud resources and scale them to fit the demand, and any predefined metrics. As a result, your company might avoid service interruptions during peak demand times.

A potential requirement for cloud bursting scenarios is workload portability. When you allow workloads to be deployed to multiple environments, you must abstract away the differences between the environments. For example, Kubernetes gives you the ability to achieve consistency at the workload level across diverse environments that use different infrastructures. For more information, see GKE Enterprise hybrid environment reference architecture.

Design considerations

The cloud bursting pattern applies to interactive and batch workloads. When you're dealing with interactive workloads, however, you must determine how to distribute requests across environments:

  • You can route incoming user requests to a load balancer that runs in the existing data center, and then have the load balancer distribute requests across the local and cloud resources.

    This approach requires the load balancer or another system that is running in the existing data center to also track the resources that are allocated in the cloud. The load balancer or another system must also initiate the automatic upscaling or downscaling of resources. Using this approach you can decommission all cloud resources during times of low activity. However, implementing mechanisms to track resources might exceed the capabilities of your load balancer solutions, and therefore increase overall complexity.

  • Instead of implementing mechanisms to track resources, you can use Cloud Load Balancing with a hybrid connectivity network endpoint group (NEG) backend. You use this load balancer to route internal client requests or external client requests to backends that are located both on-premises and in Google Cloud and that are based on different metrics, like weight-based traffic splitting. Also you can scale backends based on load balancing serving capacity for workloads in Google Cloud. For more information, see Traffic management overview for global external Application Load Balancer.

    This approach has several additional benefits, such as taking advantage of Google Cloud Armor DDoS protection capabilities, WAF, and caching content at the cloud edge using Cloud CDN. However, you need to size the hybrid network connectivity to handle the additional traffic.

  • As highlighted in Workload portability, an application might be portable to a different environment with minimal changes to achieve workload consistency, but that doesn't mean that the application performs equally the same in both environments. Differences in underlying compute, infrastructure security capabilities, or networking infrastructure, along with proximity to dependent services, typically determine performance. Through testing, you can have more accurate visibility and understand the performance expectations.

  • You can use cloud infrastructure services to build an environment to host your applications without portability. Use the following approaches to handle client requests when traffic is redirected during peak demand times:

    • Use consistent tooling to monitor and manage these two environments.
    • Ensure consistent workload versioning and that your data sources are current.
    • You might need to add automation to provision the cloud environment and reroute traffic when demand increases and the cloud workload is expected to accept client requests for your application.
  • If you intend to shut down all Google Cloud resources during times of low demand, using DNS routing policies primarily for traffic load balancing might not always be optimal. This is mainly because:

    • Resources can require some time to initialize before they can serve users.
    • DNS updates tend to propagate slowly over the internet.

    As a result:

    • Users might be routed to the Cloud environment even when no resources are available to process their requests.
    • Users might keep being routed to the on-premises environment temporarily while DNS updates propagate across the internet.

With Cloud DNS, you can choose the DNS policy and routing policy that align with your solution architecture and behavior, such as geolocation DNS routing policies. Cloud DNS also supports health checks for internal passthrough Network Load Balancer, and internal Application Load Balancer. In which case, you could incorporate it with your overall hybrid DNS setup that's based on this pattern.

In some scenarios, you can use Cloud DNS to distribute client requests with health checks on Google Cloud, like when using internal Application Load Balancers or cross-region internal Application Load Balancers. In this scenario, Cloud DNS checks the overall health of the internal Application Load Balancer, which itself checks the health of the backend instances. For more information, see Manage DNS routing policies and health checks.

You can also use Cloud DNS split horizon. Cloud DNS split horizon is an approach for setting up DNS responses or records to the specific location or network of the DNS query originator for the same domain name. This approach is commonly used to address requirements where an application is designed to offer both a private and a public experience, each with unique features. The approach also helps to distribute traffic load across environments.

Given these considerations, cloud bursting generally lends itself better to batch workloads than to interactive workloads.

Advantages

Key advantages of the cloud bursting architecture pattern include:

  • Cloud bursting lets you reuse existing investments in data centers and private computing environments. This reuse can either be permanent or in effect until existing equipment becomes due for replacement, at which point you might consider a full migration.
  • Because you no longer have to maintain excess capacity to satisfy peak demands, you might be able to increase the use and cost effectiveness of your private computing environments.
  • Cloud bursting lets you run batch jobs in a timely fashion without the need for overprovisioning compute resources.

Best practices

When implementing cloud bursting, consider the following best practices:

  • To ensure that workloads running in the cloud can access resources in the same fashion as workloads running in an on-premises environment, use the meshed pattern with the least privileged security access principle. If the workload design permits it, you can allow access only from the cloud to the on-premises computing environment, not the other way round.
  • To minimize latency for communication between environments, pick a Google Cloud region that is geographically close to your private computing environment. For more information, see Best practices for Compute Engine regions selection.
  • When using cloud bursting for batch workloads only, reduce the security attack surface by keeping all Google Cloud resources private. Disallow any direct access from the internet to these resources, even if you're using Google Cloud external load balancing to provide the entry point to the workload.
  • Select the DNS policy and routing policy that aligns with your architecture pattern and the targeted solution behavior.

    • As part of this pattern, you can apply the design of your DNS policies permanently or when you need extra capacity using another environment during peak demand times.
    • You can use geolocation DNS routing policies to have a global DNS endpoint for your regional load balancers. This tactic has many use cases for geolocation DNS routing policies, including hybrid applications that use Google Cloud alongside an on-premises deployment where Google Cloud region exists.
    • If you need to provide different records for the same DNS queries, you can use split horizon DNS—for example, queries from internal and external clients.

      For more information, see reference architectures for hybrid DNS

  • To ensure that DNS changes are propagated quickly, configure your DNS with a reasonably short time to live value so that you can reroute users to standby systems when you need extra capacity using cloud environments.

  • For jobs that aren't highly time critical, and don't store data locally, consider using Spot VM instances, which are substantially cheaper than regular VM instances. A prerequisite, however, is that if the VM job is preempted, the system must be able to automatically restart the job.

  • Use containers to achieve workload portability where applicable. Also, GKE Enterprise can be a key enabling technology for that design. For more information, see GKE Enterprise hybrid environment reference architecture.

  • Monitor any traffic sent from Google Cloud to a different computing environment. This traffic is subject to outbound data transfer charges.

  • If you plan to use this architecture long term with high outbound data transfer volume, consider using Cloud Interconnect. Cloud Interconnect can help to optimize the connectivity performance and might reduce outbound data transfer charges for traffic that meets certain conditions. For more information, see Cloud Interconnect pricing.

  • When Cloud Load Balancing is used, you should use its application capacity optimizations abilities where applicable. Doing so can help you address some of the capacity challenges that can occur in globally distributed applications.

  • Authenticate the people who use your systems by establishing common identity between environments so that systems can securely authenticate across environment boundaries.

  • To protect sensitive information, encrypting all communications in transit is highly recommended. If encryption is required at the connectivity layer, various options are available based on the selected hybrid connectivity solution. These options include VPN tunnels, HA VPN over Cloud Interconnect, and MACsec for Cloud Interconnect.

Hybrid and multicloud architecture patterns: What's next