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As businesses increasingly rely on Apache Kafka® for mission-critical applications, resiliency becomes non-negotiable. Any unplanned downtime and breaches can result in lost revenue, reputation damage, fines or audits, reduced CSAT, or critical data loss.
Therefore, a cloud service is only as useful as it is resilient. Take our customer 10x Banking (their name is coincidental), which depends on Confluent Cloud to be highly reliable and resilient for its many international banking customers.
“Customers expect banking to be flawless with financial products that are targeted and hyper-personalized for their individual needs…. We can’t have a 99.9 percent reliable platform, it has to be 100 percent.” – Mark Holt, Chief Product and Engineering Officer, 10x Banking.
We take pride in our investments in Confluent Cloud’s resiliency and the trust we’ve gained from providing a reliable service for our customers. We’ve managed 15,000+ Kafka clusters (the largest in the world) across all environments around the globe to build a cloud-native Kafka service that can handle both common and esoteric failures in the cloud. Read on to learn more about how we built Confluent Cloud to be 10x more available and durable than open source Apache Kafka.
In the context of a cloud service, resiliency means two things. Availability—the platform is always accessible—and durability—the data stored within is also protected from any anomaly such as corruption, loss, etc. Apache Kafka achieves a certain level of resiliency through replication—both across machines in a cluster and across multiple clusters in multiple data centers. However, this design is insufficient for a highly reliable data streaming service in the cloud.
Let’s take a Kafka deployment in the cloud that follows all best practices using the picture below. Here, we have three brokers running in a Kubernetes cluster and some servers, along with load balancers to increase availability. This is just for one availability zone—setting up across AZs does not happen out-of-the-box with Apache Kafka, and requires additional infrastructure with more complexity. With all these elements for just one AZ, there are several things that can go wrong:
What’s a baseline SLA and downtime we can expect for this example cloud deployment? Let’s assume our brokers are running on EC2 (max 99.5% SLA for individual instances), we have the highest available EBS volumes (99.99% SLA), and we use Amazon elastic load balancers (max 99.99% SLA). We’ll also be nice and assume the underlying Kubernetes infrastructure has a negligible effect on availability. This gives us a baseline SLA = (0.995)^3 * (0.9999)^3*(0.9999)^3 = 0.9845, assuming 3 brokers on EC2, 3 LBs, and 3 EBS volumes. We’ll be generous and round up to 99%. This translates to a potential 5,256 mins (or 3.65 days) of downtime per year, and it presumes that we’ve sized the cluster appropriately and selected the right instances given the expected workload.
That’s just theoretical—in reality, building and maintaining this level of availability takes a lot of effort and manpower. Forrester interviewed several Kafka practitioners on the total economic impact of Confluent Cloud. To support a production-grade SLA, they modeled that a typical data-intensive organization would need four additional FTEs to operate open source Kafka in year one and the resources required will increase by 50% year-over-year as customer demand rises.
It’s easy to understand why this is the case—to really simplify the process, building in a production-grade SLA would require these FTEs to:
By comparison, the interviewees said they only needed two full-time engineering resources focused on Confluent Cloud, even as demand rises. That’s because we at Confluent have spent millions of hours incorporating expertise into the service, abstracting away all these operational burdens, and bringing the benefits of the cloud without all the infrastructure and availability concerns.
Confluent Cloud promises 10x higher availability with a built-in 99.99% (“four 9s”) uptime availability SLA for our customers. This is not only one of the industry’s highest SLAs, but the most comprehensive. Why do we say that?
To start, the smallest increase in SLA means exponentially less downtime for your customers. Our example OSS Kafka deployment had a (generous) baseline SLA of 99%, with a potential downtime of 5,262 mins/year. Just two additional “.9s” in Confluent Cloud’s SLA translates to at most 52.6 mins of downtime per year. That’s 100x less downtime, and it’s why we say that Confluent cloud offers beyond 10x better availability than Apache Kafka. This is all built-in to the product: It doesn’t require all the additional FTEs to manually maintain a strong SLA on your own.
But it’s not just about the number; it’s also what is covered. Confluent Cloud’s SLA covers not only infrastructure but also Apache Kafka performance, critical bug fixes, security updates, and more—something no other hosted Kafka service can claim. It means that our systems will stay resilient to almost all major issues that can arise, even in the face of the most public of disasters.
For instance, even when AWS, Azure, and GCP each had outages that affected a cloud zone, which ravaged several critical apps and services, so far in 2022, Confluent Cloud stayed resilient and true to our improved SLA of 99.99% for MZ clusters.
Don’t just take it from us—our customers agree:
“Confluent has enabled us to put our clients’ data into the cloud because it’s resilient and reliable and we know it’s safe. Building our own Kafka capability, leveraging someone else’s Kafka capability was never going to be as resilient and reliable as using Confluent.” – Mark Holt, Chief Product and Engineering Officer, 10x Banking
How did we do this? There are a lot more improvements we’ve made over the years than what we can elaborate on in one blog post, but here are a few areas to highlight:
Building redundancy into the system design is a core strategy to ensure high availability in spite of hardware and/or software failures. For example, while Kafka service is configured to have three replicas for every Kafka topic, we make sure that these three copies are distributed across three different availability zones. This ensures that two copies are available even if an availability zone experiences failures.
In addition, we employ redundancy in the underlying infrastructure where possible. For example, we actively monitor workload and performance metrics to expand or shrink our multi-tenant clusters with excess capacity to handle workload spikes. We also enforce limits to ensure that a multi-tenant user gets the promised quotas despite any “noisy neighbors” from other tenants. We’re always refining the enforcement scheme for these thresholds to better handle highly skewed apps and workloads.
Confluent has invested heavily in proactive cloud monitoring to learn about production problems before any workload impact. We monitor each cluster with Health Check that creates synthetic loads that fully emulate the network path and logic that a customer application would follow. The metrics collected are sent to our telemetry pipelines and persisted on a data lake, where we do analysis of the historical data weekly to identify variations and trends.
As a part of the analysis, we also identify any monitoring gaps to understand if there are gaps on our internal alarms (i.e., customer escalations not caught by our monitoring). This helps us build in potential improvements to Kafka as a product, and to the underlying cloud provider services infrastructure and dependencies.
No matter how prepared we are, for various reasons, incidents do occur. When that happens, our first goal is to first mitigate and minimize customer impact. With built-in self-healing automation, Confluent Cloud auto detects the unavailability of cloud service (storage, compute, etc.) and mitigates its impact by appropriately isolating the impacted node/replica. It also auto-rebalances the cluster to add/remove or uneven workload scenarios.
Post-mitigation, we perform a detailed root cause analysis and build improvements to avoid such architectural issues in the future. An outcome of this review is to improve runbooks and monitors, improve test coverage, reduce resolution time, and improve self-healing logic to detect the citation and remediate systematically.
For any new design and feature, there is ample focus on developing extensive test plans with the aim to detect any regression before getting to production. In addition to usual unit and integration tests, we use failure injection mechanisms (Trogdor+ChaosMesh) to emulate faults and verify that each release is tolerant to those failures. In the multi-tenant environment, we also include load tests to ensure proper isolation is honored to avoid availability impact due to noisy neighbors.
Confluent Cloud’s built-in multi-zone capability helps mitigate the most common cloud outage: single availability zone failures. But as mentioned above, organizations need even higher availability to defend against another class of failure: a regional outage across public cloud providers.
To further minimize downtime and data loss in a regional outage, we introduced Cluster Linking and Schema Linking to help organizations architect a multi-region disaster recovery plan for Kafka. These built-in features enable Confluent customers to keep data and metadata in sync across 65+ regions within all three major cloud providers, or on their own on-prem infrastructure with Confluent Platform, improving the resiliency of both in-cloud and on-prem deployments. Users can create active-passive or active-active disaster recovery patterns to hit a low RPO (recovery point objective) and RTO (recovery time objective).
Because Cluster Linking is built into fully managed Confluent Cloud clusters, it’s much easier to spin up than MirrorMaker2 (the open source equivalent to replicate data across regions with Apache Kafka) without any extra infrastructure or software. Learn more about how you can easily deploy multi-region disaster recovery and failover strategy with Cluster Linking in just three steps.
Durability is the other side of resiliency, and is a measure of data integrity. Our customers use Confluent Cloud for their most critical data, and they expect it to remain intact and available when they need it, in the same form when it was written. In measuring durability, a message is considered durable when it is committed to the broker, i.e., it is acknowledged by all in-sync replicas and the high water mark has advanced. Durability score is the percentage of durable messages to the total number of messages.
Apache Kafka primarily guarantees high durability through redundancy—when the data is replicated across brokers—and in some cases across availability zones. We’ve gone far beyond this to build tooling and durability services to detect and mitigate data integrity issues, relieving operators of the burdens of monitoring data integrity themselves. At Confluent, we provide durability for an average of tens of trillions of messages per day.
How did we do this? We took a three-pronged approach to achieve the strictest of durability standards that go far beyond Apache Kafka:
We’ve made Confluent Cloud 10x more resilient than Apache Kafka so you can:
Hear from more customers about how they have offloaded operational burdens with Confluent Cloud’s built-in resiliency.
To check out other areas where we’ve made Confluent a 10x better data streaming platform, sign up for our latest 10x webinar on Sept 29th to learn from our experts about how to train a ML model with 10x elasticity and storage, or just give Confluent Cloud a go with a free trial.
We covered so much at Current 2024, from the 138 breakout sessions, lightning talks, and meetups on the expo floor to what happened on the main stage. If you heard any snippets or saw quotes from the Day 2 keynote, then you already know what I told the room: We are all data streaming engineers now.
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