Why Cache Data? [Latency Book Excerpt]
Latency is a monstrous concern here at ScyllaDB. So we’re pleased to bring you excerpts from Pekka Enberg’s new book on Latency…and a masterclass with Pekka as well! Latency is a monstrous concern here at ScyllaDB. Our engineers, our users, and our broader community are obsessed with it…to the point that we developed an entire conference on low latency. [Side note: That’s P99 CONF, a free + virtual conference coming to you live, October 22-23.] Join P99 CONF – Free + Virtual We’re delighted that Pekka Enberg decided to write an entire book on latency toScyllaDB X Cloud: An Inside Look with Avi Kivity (Part 1)
ScyllaDB’s co-founder/CTO on the motivations and architectural shifts behind ScyllaDB X Cloud — focusing on Raft and tablets-based data distribution If you follow ScyllaDB, you’ve probably heard us talking about Raft and tablets-based data distribution for a few years now. The ultimate goal of these projects (plus a few related ones) was to optimize elasticity and price performance – especially for dynamic and storage-bound workloads. And we finally hit a nice milestone along that journey: the release of ScyllaDB X Cloud. You can read about the release in our earlier blog post. Here, we wanted to share the engineering perspective on these architectural shifts. Tim Koopmans recently sat down with Avi Kivity – ScyllaDB Co-Founder and CTO – to chat about the underlying motivation and design decisions. You can watch the complete video here. But if you prefer to read, we’re writing up the highlights. This is the first blog post in a three-part series. Why ScyllaDB X Cloud? For scaling large clusters Tim: Let’s start with a big picture. What really motivated the architectural evolution behind what we know as ScyllaDB X Cloud? Was this change inevitable? How did it come into place? Avi: It came from our experience managing clusters for our customers. With the existing architecture, things like scaling up the cluster in preparation for events like Black Friday could take a long time. Since ScyllaDB can manage very large nodes (e.g., nodes with 30TB of data), moving that data onto new nodes could take a long time, sometimes a day. Also, nodes had to be added one at a time. If you had a large cluster, scaling the cluster would be a nail-biting experience. So we decided to improve that experience and, along the way, we improved many parts of the architecture. Tim: Do you have any numbers around what it used to be like to scale a large cluster? Avi: One of our large clusters has 75 nodes, each of which has around 60TB. It’s a pretty hefty cluster. It’s nice watching clusters like that on our dashboards and seeing compactions at tens of gigabytes per second aggregate across the cluster. Those clusters are churning through large amounts of data per second and carrying a huge amount of data. Now, we can scale this amount of data in minutes, maybe an hour for the most extreme cases. So it’s quite a huge change. Why ScyllaDB addressed scaling with Tablets & Raft Tim: When you think about dynamic or storage-bound workloads today, what are other databases getting wrong in this space? How did that lead you to this new approach, with tablets? Avi: “Other databases” is a huge area – there are hundreds of databases. Let’s talk about our heritage. We came from the Cassandra model. And the basic problem there was the static distribution of data. The node layout determines how data is distributed, and as long as you don’t add or remove nodes, it remains static. That means you have no flexibility. Also, the focus on having availability over consistency led to no central point for managing the topology. Without a coordinating authority, you could make only one change at a time. One of the first changes that we made was to add a coordinating authority in the form of Raft. Before, we managed topology with Gossip, which really puts cluster management responsibility on the operator. We moved it to a Raft group to centralize the management. You’ve probably heard the old proverb that anything in computer science can be solved with another layer of indirection. We did that with tablets, more or less. We inserted a layer of indirection so that instead of having a static distribution of data to nodes, it goes through a translation table. Each range of rows is mapped to a different node in a tablets table. By manipulating the tablets table, we can redirect small packages of data (specifically, 5GB – that’s pretty small for us). We can redirect the granularity of 5GB to any node and any CPU on any node. We can move those packages around at will, and those packages are moved at the line rate, so it’s no problem to fire them away at gigabits per second across the cluster. And that gives us the ability to rebalance data on a cluster or add and remove nodes very quickly. Tim: So tablets are really a new ScyllaDB abstraction? Is it an abstraction that breaks those tables into independently managed units? And I think you said the size is 5GB – is that configurable? Avi: It’s configurable, but I don’t recommend playing with it. Normally, you stay between 2.6GB and 10GB. When it reaches 10GB, it triggers a split, which will bring it back to 5GB. So each tablet will be split into two. If it goes down to 2.5GB, it will trigger a merge, merging two tablets into one larger tablet – again, bringing it back to 5GB. Tim: So ensuring that things can be dynamically split…We can move data around, rebalance across the cluster…That gives us finer-grained load distribution as well as better scalability and perhaps a bit of separation between compute and storage, right? Because we’re not necessarily tied to the size of the compute node anymore. We can have different instance types in a cluster now, as an indirect result of this change. The tipping point Tim: Avi, you said that re-architecting around tablets has been a huge shift. So what was the tipping point? Was it just that vNodes didn’t work anymore in terms of how you organize data? What was your aha moment where you said, “Yeah, I think we need to do something different here”? Avi: It was a combination of things, and since this was such a major change, we needed a lot of motivation to do it. One part of it was the inability to perform topology changes that involve more than one node at a time. Another part was that the previous streaming mechanism was very slow. Yet another part is that, because the streaming mechanism was so slow, we had to scale well in advance of exhausting the storage on the node. That required us to leave a lot of free space on the node, and that’s wasteful. We took all of this into consideration, and that was enough motivation for us to take on a multi-year change. I think it was well worth it. Tim: Multiyear…So how long ago did you start workshopping different ideas to solve? Avi: The first phase was changing topology to be strongly consistent and having a central authority to coordinate it. I think it took around a couple of years to switch to Raft topology. Before that, we switched schema management to use Raft as well. That was a separate problem, but since those two problems had the same solution, we jumped on it. We’re still not completely done. There are still a few features that are not yet fully compatible with tablets – but we see the light at the end of the tunnel now. [Stay tuned for parts 2 and 2]Be Part of Something Big – Speak at Monster Scale Summit
Share your “extreme scale engineering” expertise with ~20K like-minded engineers Whether you’re designing, implementing, or optimizing systems that are pushed to their limits, we’d love to hear about your most impressive achievements and lessons learned – at Monster Scale Summit 2026. Become a Monster Scale Summit Speaker What’s Monster Scale Summit? Monster Scale Summit is a technical conference that connects the community of people working on performance-sensitive data-intensive applications. Engineers, architects, and SREs from gamechangers around the globe will be gathering virtually to explore “monster scale” challenges with respect to extreme levels of throughput, data, and global distribution. It’s a lot like P99 CONF (also hosted by ScyllaDB) – a two-day event that’s free, fully virtual, and highly interactive. The core difference is that it’s focused on extreme scale engineering vs. all things performance. Last time, we hosted industry giants like Kelsey Hightower, Martin Kleppmann, Discord, Slack, Canva… Browse past sessions Details please! When: March 11 + 12 Where: Wherever you’d like! It’s intentionally virtual, so you can present and interact with attendees from anywhere around the world. Topics: Core topics include distributed databases, streaming and real-time processing, intriguing system designs, methods for balancing latency/concurrency/throughput, SRE techniques proven at scale, and infrastructure built for unprecedented demands. What we’re looking for: We welcome a broad range of talks about tackling the challenges that arise in the most massive, demanding environments. The conference prioritizes technical talks sharing first-hand experiences. Sessions are just 18-20 minutes – so consider this your TED Talk debut! Share your ideasBeyond Apache Cassandra
ScyllaDB is no longer “just” a faster Cassandra. In 2008, Apache Cassandra set a new standard for database scalability. Born to support Facebook’s Inbox Search, it has since been adopted by tech giants like Uber, Netflix, and Apple – where it’s run by experts who also serve as Cassandra contributors (alongside DataStax/IBM). And as its adoption scaled, Cassandra remained true to its core mission of scaling on commodity hardware with high availability. But what about performance? Simplicity? Efficiency? Elasticity? In 2015, ScyllaDB was born to go beyond Cassandra’s suboptimal resource utilization. Fresh from creating KVM and hacking the Linux kernel, the founders believed that their low-level engineering approach could squeeze considerably more power from the underlying infrastructure. The timing was ideal: just a year earlier, Netflix had published their numbers showing how to push Apache Cassandra to 1 million write RPS. This was an impressive feat, but one that required significant infrastructure investments and tuning efforts. The idea was quite simple (in theory, at least): take Apache Cassandra’s scalable architecture and reimplement it close to the metal while keeping wire protocol compatibility. Not relying on Java meant less latency variability (plus no stop the world pauses), while a unique shard-per-core architecture maximized servers’ throughput even under heavy system load. To prevent contention, everything was made asynchronous, and all these optimizations were paired with autonomous internal schedulers for minimal operational overhead. That was 10 years ago. While I can’t speak to Cassandra’s current direction, ScyllaDB evolved quite significantly since then – shifting from “just” a faster Cassandra alternative to a database with its own identity and unique feature set. Spoiler: In this video, I walk you through some key differences between ScyllaDB and how it differs from Apache Cassandra. I discuss the differences in performance, elasticity, and capabilities such as workload prioritization. You can see how ScyllaDB maps data per CPU core, scales in parallel, and de-risks topology changes—allowing it to handle millions of OPS with predictable low latencies (and without constant tuning and babysitting). ScyllaDB’s Evolution The first generation of ScyllaDB was all about raw performance. That’s when we introduced the shard-per-core asynchronous architecture, row-based cache, and advanced schedulers that achieve predictable low latencies. ScyllaDB’s second generation aimed for feature parity with Cassandra, but we actually went beyond that. For example, we introduced our Materialized views and production-ready Global Secondary Indexes (something that Cassandra still flags as experimental). Likewise, ScyllaDB also introduced support for local secondary indexes in that same year; those were just introduced in Cassandra 5 (after at least three different indexing implementations). Moreover, our Paxos implementation for lightweight transactions eliminated much of the overhead and limitations in Cassandra’s alternative implementation. The third generation marked our shift to the cloud, along with continued innovation. This is when ScyllaDB Alternator—our DynamoDB-compatible API—was introduced. We added support for ZSTD compression in 2020 (Cassandra only adopted it late in 2021). During this period, we dramatically improved repair speeds with row-level repair and introduced workload prioritization (more on this in the next section). The fourth generation of ScyllaDB emerged around the time AWS announced their i3en instance family, with high-density nodes holding up to 60TB of data (something Cassandra still struggles to handle effectively). During this period, we introduced the Incremental Compaction Strategy (ICS), allowing users to utilize up to 70% of their storage before scaling out. This later evolved into a hybrid compaction strategy (and we now support 90% storage utilization). We also introduced Change Data Capture (CDC) with a fundamentally different approach from Cassandra’s. And we significantly extended the CQL protocol with concepts such as shard-awareness, BYPASS CACHE, per-query configurable TIMEOUTs, and much more. Finally, we arrive at the fifth generation of ScyllaDB, which is still unfolding. This phase represents our path toward strong consistency and elasticity with Raft and Tablets. For more about the significance of this, read on… Capabilities That Set ScyllaDB Apart Our engineers have introduced lots of interesting features over the past decade. Based on my interactions with former Cassandra users, I think these are the most interesting to discuss here. Tablets Data Distribution Each ScyllaDB table is split into smaller fragments (“tablets”) to evenly distribute data and load across the system. Tablets bring elasticity to ScyllaDB, allowing you to instantly double, triple, or even 10x your cluster size to accommodate unpredictable traffic surges. They also enable more efficient use of storage, reaching up to 90% utilization. Since teams can quickly scale out in response to traffic spikes, they can satisfy latency SLAs without needing to overprovision “just in case.” Raft-based Strong Consistency for Metadata Raft introduces strong consistency to ScyllaDB’s metadata. Gone are the days when a schema change could push your cluster into disagreement or you’d lose access because you forgot to update the replication factor of your authentication keyspace (issues that still plague Cassandra). Workload Prioritization Workload prioritization allows you to consolidate multiple workloads under a single cluster, each with its own SLA. Basically, it controls how different workloads compete for system resources. Teams use it to prioritize urgent application requests that require immediate response times versus others that can tolerate slighter delays (e.g., large scans). Common use cases include balancing real-time vs batch processing, splitting writes from reads, and workload/infrastructure consolidation. Repair-based Operations Repair-based operations ensure your cluster data stays in sync, even during topology changes. This addresses a long-standing data consistency flaw in Apache Cassandra, where operations like replacing failed nodes can result in data loss. ScyllaDB also fully eliminates the problem of data resurrection, thanks to repair-based tombstone garbage collection. Incremental Compaction Incremental compaction (ICS) has been the default compaction strategy in ScyllaDB for over five years. ICS greatly reduces the temporary space amplification, resulting in more disk space being available for storing user data – and that eliminates the typical requirement of 50% free space in your drive. There is no comparable Cassandra feature. Cassandra just recently introduced Unified Compaction, which has yet to prove itself. Row-based Cache ScyllaDB’s row-based cache is also unique. It is enabled by default and requires no manual tuning. With the BYPASS CACHE extension, you can prevent cache pollution by keeping important items from being invalidated. Additionally, SSTable index caching significantly reduces I/O access time when fetching data from disk. Per-shard Concurrency Limits and Rate Limiters ScyllaDB includes per-shard concurrency limits and rate limiters per partition to protect against unexpected spikes. Whether dealing with a misbehaving client or a flood of requests to a specific key, ScyllaDB ensures resilience where Cassandra often falls short. DynamoDB Compatibility ScyllaDB also offers a DynamoDB-compatible layer, further distancing itself from its Apache Cassandra origins. This lets teams run their DynamoDB workloads on any cloud or on-prem – without code changes, and with 50% lower cost. This has helped quite a few teams consolidate multiple workloads on ScyllaDB. What’s Next? At the recent Monster SCALE Summit, CEO/co-founder Dor Laor shared a peek at what’s next for ScyllaDB. A few highlights… Ready now (see this blog post and product page for details): The ability to safely run at 90% storage utilization Support for clusters with mixed instance type nodes Dynamic provisioning and flex credit Short-term: Vector search Strongly consistent tables Fault injection service Transparent repairs Object and tiered storage Raft for strongly consistent tables Longer-term Multi-key transactions Analytics and transformations with UDFs Automated large partition balancing Immutable infrastructure for greater stability and reliability A replication mode for more flexible and efficient infrastructure changes For details, watch the complete talk here: To close, ScyllaDB is faster than Cassandra (I’ll share our latest benchmark results here soon). But both ScyllaDB and Cassandra have evolved to the point that ScyllaDB is no longer “just” a faster Cassandra. We’ve evolved beyond Cassandra. If your project needs more predictable performance – and/or could benefit from the elasticity, efficiency, and simplicity optimizations we’ve been focusing on for years now – you might also want to consider evolving beyond Cassandra.We Built a Tool to Diagnose ScyllaDB Kubernetes Issues
Introducing Scylla Operator Analyze, a tool to help platform engineers and administrators deploy ScyllaDB clusters running on Kubernetes Imagine it’s a Friday afternoon. Your company is migrating all the data to ScyllaDB and you’re in the middle of setting up the cluster on Kubernetes. Then, something goes wrong. Your time today is limited, but the sheer volume of ScyllaDB configuration feels endless. To help you detect problems in ScyllaDB deployments, we built Scylla Operator Analyze, a command-line tool designed to automatically analyze Kubernetes-based ScyllaDB clusters, identify potential misconfigurations, and offer actionable diagnostics. In modern infrastructure management, Kubernetes has revolutionized how we orchestrate containers and manage distributed systems. However, debugging complex Kubernetes deployments remains a significant challenge, especially in production-grade, high-performance environments like those powered by ScyllaDB. In this blog post, we’ll explain what Scylla Operator Analyze is, how it works, and how it may help platform engineers and administrators deploy ScyllaDB clusters running on Kubernetes. The repo we’ve been working on is available here. It’s a fork of Scylla Operator, but the project hasn’t been merged upstream (it’s highly experimental). What is Scylla Operator Analyze? Scylla Operator Analyze is a Go-based command-line utility that extends Scylla Operator by introducing a diagnostic command. Its goal is straightforward: automatically inspect a given Kubernetes deployment and report problems it identified in the deployment configuration. We designed our tool to help ScyllaDB’s technical support staff to quickly diagnose known issues reported by our clients, both by providing solutions for simple problems, and helpful insights in more complex cases. However, it’s also freely available as a subcommand of the Scylla Operator binary. The next few sections share how we implemented the tool. If you want to go straight to example usage, skip to the Making a diagnosis section. Capturing the cluster state Kubernetes deployments consist of many components with various functions. Collectively, they are called resources. The Kubernetes API presents them to the client as objects containing fields with information about their configuration and current state. Two modes of operation Scylla Operator Analyze supports two ways of collecting these data: Live Cluster Connection The tool can connect directly to a Kubernetes cluster using the client-go API. Once connected, it retrieves data from Kubernetes resources and compiles it into an internal representation. Archive-Based Analysis (Must-Gather) Alternatively, the tool can analyze archived cluster states created using a utility calledmust-gather. These archives
contain YAML descriptions of resources, allowing offline analysis.
Diagnosis by analyzing symptoms Symptoms are high-level objects
representing certain issues that could occur while deploying a
ScyllaDB cluster. A symptom contains the diagnosis of the problem
and a suggestion on how to fix it, as well as a method for checking
if the problem occurs in a given deployment (we cover this in the
section about selectors). In order to create objects representing
more complex problems, symptoms can be used to create tree-like
structures. For example, a problem that could manifest itself in a
few different ways could be represented by many symptoms checking
for all the different spots the problem could affect. Those
symptoms would be connected to one root symptom, describing the
cause of the problem. This way, if any of the sub-symptoms report
that their condition is met, the tool can display the root cause
instead of one specific manifestation of that problem. Example
of a symptom and the workflow used to detect it. In this
example, let’s assume that the driver is unable to provide storage,
but NodeConfig does not report a nonexistent device. When checking
if the symptom occurs, the tool will perform the following steps.
Check if the NodeConfig reports a nonexistent device – no Check if
the driver is unable to provide storage – yes. At this point we
know the symptom occurs, so we don’t need to check for any more
subsymptoms. Since one of the subsymptoms occurs, the main symptom
(NodeConfig configured with nonexistent volume) is reported to the
user. Deployment condition description Resources As described
earlier, Kubernetes deployments can be considered collections of
many interconnected resources. All resources are described using
so-called fields. Fields contain information identifying resources,
deployment configuration and descriptions of past and current
states. Together, these data give the controllers all the
information they need to supervise the deployment. Because of that,
they are very useful for debugging issues and are the main source
of information for our tool. Resources’ fields contain a special
kind field, which describes what the resource is and
indicates what other fields are available. Some fundamental
Kubernetes resource kinds include Pods, Services, etc. Those can
also be extended with custom ones, such as the
ScyllaCluster resource kind defined by the Scylla
Operator. This provides the most basic kind of grouping of
resources in Kubernetes. Other fields are grouped in sections
called Metadata, which provide identifying information,
Spec, which contain configuration and Status,
which contain current status. Such a description in YAML format may
look something like this: apiVersion: v1 kind: Pod metadata:
creationTimestamp: "2024-12-03T17:47:06Z" labels: scylla/cluster:
scylla scylla/datacenter: us-east-1 scylla/scylla-version: 6.2.0
name: scylla-us-east-1-us-east-1a-0 namespace: scylla spec:
volumes: - name: data persistentVolumeClaim: claimName:
data-scylla-us-east-1-us-east-1a-0 status: conditions: -
lastTransitionTime: "2024-12-03T17:47:06Z" message: '0/1 nodes are
available: pod has unbound immediate PersistentVolumeClaims.
preemption: 0/1 nodes are available: 1 Preemption is not helpful
for scheduling.' reason: Unschedulable status: "False" type:
PodScheduled phase: Pending Selectors An accurate
description of symptoms (presented in the previous section)
requires a method for describing conditions in the deployment using
information contained in the resources’ fields. Moreover, because
of the distributed nature of both Kubernetes deployments and
ScyllaDB, these descriptions must also specify how the resources
are related to one another. Our tool comes with a package providing
selectors. They offer a simple, yet powerful, way to
describe deployment conditions using Kubernetes objects in a way
that’s flexible and allows for automatic processing using the
provided selection engine. A selector can be thought of as a query
because it specifies the kinds of resources to select and criteria
which they should satisfy. Selectors are constructed using four
main methods of the selector structure builder. First, the
developer specifies resources to be selected with the
Select method by specifying their kind and a predicate
which should be true for the selected resources. The predicate is
provided as a standard Go closure to allow for complex conditions
if needed. Next, the developer may call the Relate method
to define a relationship between two kinds of resources. This is
again defined using a Go closure as a predicate, which must hold
for the two objects to be considered in the same result set. This
can establish a context within which an issue should be inspected
(for example: connecting a Pod to relevant Storage resources).
Finally, constraints for individual resources in the result set can
be specified with the Where method, similarly to how it is
done in the Select method. This method is mainly meant to
be used with the SelectWithNil method. The
SelectWithNil method is the same as the Select
method; the only difference is that it allows returning a special
nil value instead of a resource instance. This
nil value signifies that no resources of a given
kind match all the other resources in the resulting set. Thanks to
this, selectors can also be used to detect a scenario where a
resource is missing just by examining the context of related
resources. An example selector — shortened for brevity — may look
something like this: selector. New(). Select("scylla-pod",
selector.Type[*v1.Pod](), func(p *v1.Pod) (bool, error) { /* ... */
}). SelectWithNil("storage-class",
selector.Type[*storagev1.StorageClass](), nil). Select("pod-pvc",
selector.Type[*v1.PersistentVolumeClaim](), nil).
Relate("scylla-pod", "pod-pvc", func(p *v1.Pod, pvc
*v1.PersistentVolumeClaim) (bool, error) { for _, volume := range
p.Spec.Volumes { vPvc := volume.PersistentVolumeClaim if vPvc !=
nil && (*vPvc).ClaimName == pvc.Name { return true, nil } }
return false, nil }). Relate("pod-pvc", "storage-class", /* ...
*/). Where("storage-class", func(sc *storagev1.StorageClass) (bool,
error) { return sc == nil, nil }) In symptom definitions,
selectors for a corresponding condition are used and are usually
constructed alongside them. Such a selector provides a description
of a faulty condition. This means that if there is a matching set
of resources, it can be inferred that the symptom occurs. Finally,
the selector can then be used, given all the deployments resources,
to construct an iterator-like object that provides a list of all
the sets of resources that match the selector. Symptoms can then
use those results to detect issues and generate diagnoses
containing useful debugging information. Making a diagnosis When a
symptom relating to a problematic condition is detected, a
diagnosis for a user is generated. Diagnoses are
automatically generated report objects summarizing the problem and
providing additional information. A diagnosis consists of
an issue description, identifiers of resources related to the
fault, and hints for the user (when available). Hints may contain,
for example, a description of steps to remedy the issue or a
reference to a bug tracker. In the final stage of analysis, those
diagnoses are presented to the user and the output may look
something like this: Diagnoses: scylladb-local-xfs StorageClass
used by a ScyllaCluster is missing Suggestions: deploy
scylladb-local-xfs StorageClass (or change StorageClass) Resources
GVK: /v1.PersistentVolumeClaim,
scylla/data-scylla-us-east-1-us-east-1a-0 (4…)
scylla.scylladb.com/v1.ScyllaCluster, scylla/scylla
(b6343b79-4887-497b…) /v1.Pod, scylla/scylla-us-east-1-us-east-1a-0
(0e716c3f-6432-4eeb-b5ff-…) Learn more As we suggested, Kubernetes
deployments of ScyllaDB involve many interacting components, each
of which has its own quirks. Here are a few strategies to help in
diagnosing the problems you encounter: Run
Scylla Doctor Check our troubleshooting
guide Look for open
issues on our GitHub Check our forum Ask us on Slack Learn more about
ScyllaDB at ScyllaDB
University Good luck, fellow troubleshooter! Building easy-cass-mcp: An MCP Server for Cassandra Operations
I’ve started working on a new project that I’d like to share, easy-cass-mcp, an MCP (Model Context Protocol) server specifically designed to assist Apache Cassandra operators.
After spending over a decade optimizing Cassandra clusters in production environments, I’ve seen teams consistently struggle with how to interpret system metrics, configuration settings, schema design, and system configuration, and most importantly, how to understand how they all impact each other. While many teams have solid monitoring through JMX-based collectors, extracting and contextualizing specific operational metrics for troubleshooting or optimization can still be cumbersome. The good news is that we now have the infrastructure to make all this operational knowledge accessible through conversational AI.
