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Failover Solutions

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Network Management

Failover solutions provide automated redundancy and continuity of operations in the event of failures. Failover systems enable rapid switching to standby components or backup data centers with minimal service interruption during outages or maintenance.

What is Failover?

Failover refers to automatically switching operations to a redundant standby site or system when the primary fails or becomes unavailable.

For example, a failover cluster would activate a standby server if the primary server encounters a hardware failure. A database failover would promote a read replica to replace a crashed primary database server.

Failover solutions aim to provide high availability and uptime despite failures. Key objectives include:

  • Minimizing service downtime and disruption during outages
  • Masking failures from end users for transparency
  • Reducing business and revenue losses from operational issues
  • Ensuring resilience of critical applications and infrastructure
  • Facilitating maintenance without affecting services

How Failover Works

Failover involves standing up redundant infrastructure or services that can seamlessly takeover when the primary fails:

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Health monitoring systems continuously track the availability and performance of primary failover components. They initiate failover when defined triggers occur like a server crashing or network latency spikes.

Redundant components like servers, networks, and data centers are maintained in a synchronized standby state, ready to be activated. These are sized to handle the full production load.

The failover mechanism automatically and seamlessly switches operations from the failed primary to the standby.

For example, a primary data center outage would trigger failing over applications and data to a secondary standby site. Backup power systems also enable redundancy against utility failures.

The goal is to minimize the transition time between primary and secondary systems to reduce downtime and disruption during outages or maintenance events.

Types of Failover

There are several failover types and methods:

Component Failover

Specific components like servers, routers, and disks failover to identical standbys:

  • Failover Clustering – Servers are clustered with shared storage for redundancy. If a node fails, its applications are restarted on other nodes.
  • Load Balancer Failover – Distributes traffic across multiple redundant load balancers. If one fails, others continue processing requests.
  • Link Failover – Reroutes network traffic to standby links if a primary link goes down. Useful for high-uptime MPLS and broadband links.

Site Failover

An entire data center or cloud region fails over to a secondary standby site:

  • Active-Passive – Services run at the primary site. The backup site is idle until activated during failover. This option is cost-effective, but recovery might be slower.
  • Active-Active – Both sites are concurrently active, spreading the load in normal operation. It provides faster failover to the remaining site, but uses more resources.
  • Cloud Site Resiliency – Cloud providers, like AWS and Azure, natively replicate across regions, enabling failover between them.

Database Failover

Database systems maintain redundant standby database servers and data replicas:

  • Read replicas – Copies of database servers that can be promoted to replace failed masters and used by MySQL, Postgres, etc.
  • Database mirroring – A live database replica is maintained synchronized via transaction log shipping for high availability as seen in SQL Server.
  • Sharding – The database is horizontally partitioned across servers, so failure of subsets allows partial availability.

Example Failover Setup

A common high-availability setup may combine multiple failover layers:

  • Redundant internet links from multiple ISPs failover using dynamic routing when an uplink fails.
  • Site redundancy with active-passive data centers in different geographic regions for disaster recovery.
  • Load-balanced web servers create redundancy for web applications. Failed nodes are automatically removed from the pool.
  • Clustered database servers using mirroring synchronizes a live redundant database for rapid failover.
  • Backups to external storage protect against data corruption. It can restore if both data centers fail.

This defense-in-depth approach provides resiliency against failures at multiple levels.

Failover Architectures

Typical failover architectures include:

Cold Standby

Dormant spare servers and data replicas are powered off until needed. This approach minimizes costs but incurs delay in activating backups after a failure.

Warm Standby

Redundant infrastructure runs idly, ready to be switched into service rapidly. This provides a balance of readiness and resource usage.

Hot Standby

Full operations are concurrently active across primary and backup systems for the fastest possible failover. This is the most resource-intensive failover architecture.

Pilot Light

Minimal version of application runs at backup keeping key state synchronized. This is faster than cold standby, but uses less resources than warm standby.

Failover Best Practices

When architecting failover solutions, follow these best practices:

  • Eliminate single points of failure – Build adequate redundancy at all layers including networks, power, cooling, servers.
  • Regularly test failover – Validate recovery plans via simulations to confirm failover effectiveness.
  • Monitor health proactively – Instrument systems for early problem detection before failures occur.
  • Automate failover – Use automatic failover to accelerate recovery after incidents.
  • Manage failback carefully – Controlled failback once issues are fixed prevents a fragile primary from recurring problems.
  • Documentation – Maintain updated failover runbooks for smooth execution by operations teams.
  • Review failures – Analyze failover events as lessons learned to strengthen resilience.
  • Layered resilience – Combine redundancy across components, systems, and sites for defense-in-depth.
  • Balance costs – Size standbys based on failure likelihood and recovery goals.

Following these best practices can maximize the reliability improvements from failover.

Implementing Failover

Considerations when implementing failover include:

  • Redundancy levels and cost vs. allowed simultaneous failures
  • Automating failover vs. slower manual processes
  • Validating capabilities through testing and fire drills
  • Sync frequency between primaries and secondaries
  • Failback policies after recovery
  • Visibility into failover events and alerts
  • Documentation for smooth failover execution

Benefits of Failover

Failover solutions provide many benefits:

  • High availability during outages
  • Operational resilience
  • Reduced maintenance impact
  • Compliance with regulations
  • Scalability for demand spikes
  • Data protection against disasters

For mission-critical systems, the benefits far outweigh the costs. However, it’s important that designs are balanced to avoid over-engineering at excess cost.

See how Imperva Site Failover can help you with failover.

Conclusion

Failover capabilities are essential for service reliability and uptime. Organizations utilize various failover systems like clustering, replication, and redundancy to withstand outages and disasters. As services become increasingly complex and distributed across regions, failover solutions will be more crucial in ensuring resilience.