ScyllaDB R&D Year in Review: Elasticity, Efficiency, and Real-Time Vector Search

31 March 2026, 12:03 pm by ScyllaDB

Learn about ScyllaDB’s new features, performance improvements, and innovations — plus, get a sneak peek into what’s coming next. 2025 was a busy year for ScyllaDB R&D. We shipped one major release, three minor releases, and a continuous stream of updates across both ScyllaDB and ScyllaDB Cloud. Our users are most excited about elasticity, vector search, and reduced total cost of ownership. We also made nice progress on years-long projects like strong consistency and object storage I raced through a year-in-review recap in my recent Monster Scale Summit talk (time limits, sorry), which you can watch on-demand. But I also want to share a written version that links to related talks and blog posts with additional detail. Feel free to choose your own adventure. Watch the talk Tablets: Fast Elasticity ScyllaDB’s “tablets” data distribution approach is now fully supported across all ScyllaDB capabilities, for both CQL and Alternator (our DynamoDB-compatible API). Tablets are the key technology that dynamically scales clusters in and out. It’s been in production for over a year now; some customers use it to scale for the usual daily fluctuations, others rely on its fast responses to workload volatility like expected events, unpredictable spikes, etc. Right now, the autoscaling lets users maximize their disks, which reduces costs. Soon, we’ll automatically scale based on workload characteristics as well as storage. A few things make this genuinely different from the vNodes design that we originally inherited from Cassandra, but replaced with tablets: When you add new nodes, load balancing starts immediately and in parallel. No cleanup operation is needed. There’s also no resharding; rebalancing is automated. Moreover, we shifted from mutation-based streaming to file-based streaming: stream the entire SSTable files without deserializing them into mutation fragments and reserializing them back into SSTables on receiving nodes. As a result, 3X less data is streamed over the network and less CPU is consumed, especially for data models that contain small cells. This change provides up to 25X faster streaming. As Avi’s talk explains, we can scale out in minutes and the tablets load balancing algorithm balances nodes based on their storage consumption. That means more usable space on an ongoing basis – up to 90% disk utilization. Also noteworthy: you can now scale with different node sizes – so you can increase capacity in much smaller increments. You can add tiny instances first, then replace them with larger ones if needed. That means you rarely pay for unused capacity. For example, before, if you started with an i4i.16xlarge node that had 15 TB of storage and you hit 70% utilization, you had to launch another i4i.16xlarge – adding 15 TB at once. Now, you might add two xlarge nodes (1.8 TB each) first. Then, if you need more storage, you add more small nodes, and eventually replace them with larger nodes. Vector Search: Real-Time AI Customers like Tripadvisor, ShareChat, Medium, and Agoda have been using ScyllaDB as a fast feature store in their AI pipelines for several years now. Now, ScyllaDB also has real-time vector search, which is embedded in ScyllaDB Cloud. Our vector search takes advantage of ScyllaDB’s unique architecture. Technologies like our super-fast Rust driver, CDC, and tablets help us deliver real-time AI queries. We can handle datasets of 1 billion vectors with P99 latency as low as 1.7 ms and throughput up to 252,000 QPS. Dictionary-Based Compression I’ve always been interested in compression, even as a student. It’s particularly interesting for databases, though. It allows you to deliver more with less, so it’s yet another way to reduce costs. ScyllaDB Cloud has always had compression enabled by default, both for data at rest and for data in transit. We compress our SSTables on disk, we compress traffic between nodes, and optionally between clients and nodes. In 2025, we improved its efficiency up to 80% by enabling dictionary-based compression. The compressor gains better context of the data being compressed. That gives it higher compression ratios and, in some cases, even better performance. Our two most popular compression algorithms, LZ4 and ZSTD, both benefit from dictionaries now. It works by sampling some data, from which it creates a dictionary and then uses it to further compress the data. The graph on the lower left shows the impact of enabling dictionary compression for network traffic. Both compression algorithms are working and both drop nicely – from 70% to less than 50% for LZ4 and from around 50% to 33% for ZSTD. The table on the lower right shows a similar change. It shows the benefit for disk utilization on a customer’s production cluster, essentially cutting down storage consumption from 50% to less than 30%. Note that the 50% was an already compressed dataset. With this new compression, we further compressed it to less than 30%, a significant saving. Raft-Based Topology We’ve been working on Raft and features built on top of it for several years now. Currently, we use Raft for multiple purposes. Schema consistency was the first step, but topology is the more interesting improvement. With Raft-based fast parallel scaling and safe schema updates, we’re ready to finally retire Gossip-based topology. Other features that use Raft-based topology are authentication, service levels (also known as workload prioritization), and tablets. We are actively working on making strong consistency available for data as well. ScyllaDB X Cloud ScyllaDB X Cloud is the next generation of ScyllaDB Cloud, a truly elastic database-as-a-service. It builds upon innovation in both ScyllaDB core (such as tablets and Raft-based topology), as well as innovation and improvements in ScyllaDB Cloud itself (such as parallel setup of cloud resources, reduced boot time, and the new resource resizing algorithm) to provide immediate elasticity to clusters. Curious how it works? It’s quite simple, really. You just select two important parameters for your cluster, and those define the minimum values for resources: The minimum vCPU count, which is a way to measure the ‘horsepower’ that you initially want to reserve for your clusters. The minimum storage size. And that’s it. You can do this via the API or UI. In the UI, it looks like this: If you wish, you can also limit it to a specific instance family. Now, let’s see how this scaling looks in action. A few things to note here: There are three somewhat large nodes and three additional nodes that are smaller. Some of the tablets are not equal, and that’s perfectly fine. The load was very high initially, then additional load moved gradually to the new nodes. The workload itself, in terms of requests, didn’t change. It changed which nodes it is going to, but the overall value remained the same. The average latency, the P95 latency, and the P99 latency are all great: even the P99s are in the single-digit milliseconds. And here’s a look at additional ScyllaDB Cloud updates before we move on: A Few More Things We Shipped Last Year Backup is a critical feature of any database, and we run it regularly in ScyllaDB Cloud for our customers. In the past, we used an external utility that backed up snapshots of the data. That was somewhat inefficient. Also, it competed with the memory, CPU, disk, and network resources that ScyllaDB was consuming – potentially affecting the throughput and latency of user workloads. We reimplemented the backup client so it now runs inside ScyllaDB’s scheduler and cooperates with the rest of the system. The result is minimal impact on user workload and 11X faster execution that scales linearly with the number of shards per node. On the infrastructure side, the new AWS Graviton i8g instances proved themselves this year. We measured up to 2X throughput and lower latency at the same price, along with higher usable storage from improved compression and utilization. We don’t embrace every new instance type since we have very specific and demanding requirements. However, when we see clear value like this, we encourage customers to move to newer generations. On the security side, all new clusters now have their data encrypted at rest by default. When creating a cluster, you can either use your own key (known as ‘BYOK’) or use the ScyllaDB Cloud key. We also reached general availability of our Rust driver. This is interesting because it’s our fastest driver. Also, its binding is the foundation for our grand plan: unifying our drivers under the Rust infrastructure. We started with a new C++ driver. Next up (almost ready) is our NodeJS driver – and we’ll continue with others as well. We also released our C# driver (another popular demand) and across the board improved our drivers’ reliability, capabilities, compatibility, and performance. Finally, our Alternator clients in various languages received some important updates as well, such as network compression to both requests and responses. What’s Next for ScyllaDB Finally, let’s close with a glimpse at some of the major things we are expecting to deliver in 2026: An efficient, easy-to-use, and online process for migrating from vNodes to tablets. Strong data consistency for data (beyond metadata and internal features). A fast dedicated data path to key-value data Additional capabilities focused on 1) improved total cost of ownership and 2) more real-time AI features and integrations. There’s a lot to look forward to! We’d love to answer questions or hear your feedback.

Rethinking “Designing Data-Intensive Applications”

26 March 2026, 12:06 pm by ScyllaDB

How Martin Kleppmann’s iconic book evolved for AI and cloud-native architectures Since its release in 2017, Designing Data-Intensive Applications (DDIA) has become known as the bible for anyone working on large-scale, data-driven systems. The book’s focus on fundamentals (like storage engines, replication, and partitioning) has helped it age well. Still, the world of distributed systems has evolved substantially in the past decade. Cloud-native architectures are now the default. Object storage has become a first-class building block. Databases increasingly run everywhere from embedded and edge deployments to fully managed cloud services. And AI-driven workloads have made a mark on storage formats, query engines, and indexing strategies. So, after years of requests for a second edition, Martin Kleppmann revisited the book – and he enlisted his longtime collaborator Chris Riccomini as a co-author. Their goal: Keep the core intact while weaving in new ideas and refreshing the details throughout. With the second edition of DDIA now arriving at people’s doorsteps, let’s look at what Kleppmann and Riccomini shared about the project at Monster Scale Summit 2025. That conversation was recorded mid-revision. You can watch the entire chat or read highlights below.  Extra: Hear what Kleppmann and Riccomini had to say when the book went off to the printers this year.  They were featured again at Monster SCALE Summit 2026, which just concluded. This talk is available on-demand, alongside 60+ others by antirez, Pat Helland, Camille Fournier, Discord, Disney, and  more. People have been requesting a second edition for a while – why now? Kleppmann: Yeah, I’ve long wanted to do a second edition, but I also have a lot of other things I want to do, so it’s always a matter of prioritization. In the end, though, I felt that the technology had moved on enough. Most of the book focuses on fundamental concepts that don’t change that quickly. They change on the timescale of decades, not months. In that sense, it’s a nice book to revise, because there aren’t that many big changes. At the same time, many details have changed. The biggest one is how people use cloud services today compared to ten years ago. Cloud existed back then, of course, but I think its impact on data systems architecture has only been felt in the last few years. That’s something we’re trying to work in throughout the second edition of the book. How have database architectures evolved since the first edition? Riccomini: I’ve been thinking about whether database architecture has changed now that we’re putting databases in more places – cloud, BYOC, on-prem, on-client, on-edge, etc. I think so. I have a hypothesis that successful future databases will be able to move or scale with you, from your laptop, to your server, to your cloud, and even to another cloud. We’re already seeing evidence of this with things like DuckDB and MotherDuck, which span embedded to cloud-based use cases. I think PGlite and Postgres are another example, where you see Postgres being embedded. SQLite is an obvious signal on the embedded side. On the query engine side, you see this with systems like Daft, which can run locally and in a distributed setting. So the answer is yes. The biggest shift is the split between control, data, and compute planes. That architecture is widely accepted now and has proven flexible when moving between SaaS and BYOC. There’s also an operational aspect to this. When you talk about SaaS versus non-SaaS, you’re talking about things like multi-tenancy and how much you can leverage cloud-provider infrastructure. I had an interesting discussion about Confluent Freight versus WarpStream, two competing Kafka streaming systems. Freight is built to take advantage of a lot of the in-cloud SaaS infrastructure Confluent has, while WarpStream is built more like a BYOC system and doesn’t rely on things like a custom network plane. Operationally, there’s a lot to consider regarding security and multi-tenancy, and I’m not sure we’re as far along as we could be. A lot of what SaaS companies are doing still feels proprietary and internal. That’s my read on the situation. Kleppmann: I’d add a little to that. At the time of the first edition, the model for databases was that a node ran on a machine, storing data on its local file system. Storage was local disks, and replication happened at the application layer on top of that. Now we’re increasingly seeing a model where storage is an object store. It’s not a local file system; it’s a remote service, and it’s already replicated. Building on top of an abstraction like object storage lets you do fundamentally different things compared to local disk storage. I’m not saying one is better than the other – there are always tradeoffs. But this represents a new point in the tradeoff space that really wasn’t present at the time of the first edition. Of course, object stores existed back then, but far fewer databases took advantage of them in the way people do now. We’ve seen a proliferation of specialized databases recently – do you think we’re moving toward consolidation? Riccomini: With my investment hat on, this is the million-dollar…or billion-dollar…question. Which of these is it? I think the answer is probably both. The reality is that Postgres has really taken the world by storm lately, and its extension ecosystem has become pretty robust in recent versions. For most people, when they’re starting out, they’re naturally going to build on something like Postgres. They’ll use pg\_search or something similar for their search index, pgvector for vector embeddings, and PG analytics or pg\_duckdb for their data lake. Then the question is: as they scale, will that still be okay? And in some cases, yes. In other cases, no. My personal hypothesis is that as you not only scale up but also need features that are core to your product, you’re more likely to move to a specialized system. pgvector, for example, is a reasonable starting point. But if your entire product is like Cursor AI or an IDE that does code completion, you probably need something more robust and scalable than pgvector can provide. At that point, you’d likely look at something like Pinecone or Turbopuffer or companies like that. So I think it’s both. And because Postgres is going to eat the bottom of the market, I do think there will be fewer specialized vendors, but I don’t think they’ll disappear entirely. What are some of the key tradeoffs you see with streaming systems today? Kleppmann: Streaming sits in a slightly weird space. A typical stream processor has a one-record-at-a-time, callback-based API. It’s very imperative. On top of that, you can build things like relational operators and query plans. But if you keep pushing in that direction, the result starts to look much more like a database that does incremental view maintenance. There are projects like Materialize that are aiming there. You just give it a SQL query, and the fact that it’s streaming is an implementation detail that’s almost hidden. I don’t know if that means the result for many of these systems is this: if you have a query you can express in SQL, you hand it off to one of these systems and let it maintain the view. And what we currently think of as streaming, with the lower-level APIs, is used for a more specialized set of applications. That might be very high-scale use cases, or queries that just don’t fit well into a relational style. Riccomini: Another thing I’d add is the fundamental tradeoff between latency and throughput, which most streaming systems have to deal with. Ideally, you want the lowest possible latency. But when you do that, it becomes harder to get higher throughput. The usual way to increase throughput is to batch writes. But as soon as you start batching writes, you increase the latency between when a message is sent and when it’s received. How is AI impacting data-intensive applications? Kleppmann: There’s some AI-plus-data work we’ve been exploring in research (not really part of the book). The idea is this: if you want to give an AI some control over a system – if it’s allowed to press buttons that affect data, like editing or updating it – then the safest way to do that is through a well-defined API. That API defines which buttons the AI is allowed to press, and those actions correspond to things that make sense and maybe fulfill certain consistency properties. More generally, it seems important to have interfaces that allow AI agents and humans to work safely together, with the database as common ground. Humans can update data, the AI can update data, and both can see each other’s changes. You can imagine workflows where changes are reviewed, compared, and merged. Those kinds of processes will be necessary if we want good collaboration between humans and AI systems. Riccomini: From an implementation perspective, storage formats are definitely going to evolve. We’re already seeing this with systems like LanceDB, which are trying to support multimodal data better. Arrow, for example, is built for columnar data, which may not be the best fit for some multimodal use cases. And this goes beyond storage into things like Arrow RPC as well. On the query engine side, there’s also a lot of ongoing work around query optimization and indexing. The idea is to build smarter databases that can look at query patterns and adjust themselves over time. There was a good paper from Google a while back that used more traditional machine learning techniques to do dynamic indexing based on query patterns. That line of work will continue. And then, of course, support for embeddings, vector search, and semantic search will become more common. Good integrations with RAG (Retrieval-Augmented Generation)…that’s also important. We’re still very much at the forefront of all of this, so it’s tricky. Watch the 2026 Chat with Martin and Chris

Monster SCALE Summit 2026 Recap: From Database Elasticity to Nanosecond AI

23 March 2026, 7:42 pm by ScyllaDB

It seemed like just yesterday I was here in the US hosting P99 CONF…and then suddenly I’m back again for Monster SCALE Summit 2026. The pace of it all says something – not so much about my travel between the US and Australia, but about how quickly this space is moving. Monster SCALE Summit delivered an overwhelming amount of content – so much that you need both time and distance to process it all. Sitting here now at Los Angeles International Airport, I can conclude this was the strongest summit to date. Watch sessions on-demand Day 1 To start with, the keynotes. As expected, Dor Laor set the tone with a strong opening – making a clear case that elasticity is the defining capability behind ScyllaDB operating at scale. “Elastic” is one of those overloaded terms in cloud infrastructure, but the distinction here was sharp. The focus was on a database that continuously adapts under load without breaking performance. Hot on the heels of Dor was the team from Discord, showing us just how they operate at scale while automating everything from standing up new clusters to expanding them under load, all with ScyllaDB. What stood out wasn’t just the scale but also the level of automation. I mention it at every conference, but [Discord engineer] Bo Ingram’s ScyllaDB in Action book is required reading for anyone running databases at scale. Since the conference was hosted by ScyllaDB, there was no shortage of deep dives into operating at scale. Felipe Cardeneti Mendes, author of Database Performance at Scale, expanded on the engineering behind ScyllaDB. Tablets play a key role as a core abstraction that links predictable performance with true elasticity. If you didn’t get a chance to participate in any of the live lounge events watching Felipe scale ScyllaDB to millions of operations per second, then you can try it yourself. The gap between demo and production is enticingly small, so it’s well worth a whirl. From the customer side, Freshworks and ShareChat, both with their own grounded presentations about super low latency and super low costs, focused on what actually matters in production. Enough of ScyllaDB for a bit, though. Let me recommend Joy Gao’s presentation from ClickHouse about cross-system database replication at petabyte scale. As you would expect, that’s a difficult problem to solve. Or if you want to know about ad reporting at scale, then check out the presentation from Pinterest. The presentation of the day for me was Thea Aarrestad talking about nanosecond AI at the Large Hadron Collider. The metrics in this presentation were insane, with datasets far exceeding the size of the Netflix catalog being generated per second… all in the pursuit of capturing the rarest particle interactions in real time. It’s a useful reminder that at true extreme scale, you don’t store then analyze. Instead, you analyze inline, or you lose the data forever. A big thanks to Thea. We asked for monster scale, and you certainly delivered. At the end of day one, we had another dense block of quality content from equally strong presenters. Long-time favourite, Ben Cane from American Express, is always entertaining and informative. We had some great research presented by Murat Demirbas from MongoDB around designing for distributed systems. And on the topic of distributed systems, Stephanie Wang showed us how to avoid some distributed traps with fast, simple analytics using DuckDB. Miguel Young de la Sota from Buf Technologies indulged us with speedrunning Super Mario 64 and its relationship to performance engineering. In parallel, Yaniv from ScyllaDB core engineering showed us what’s new and what’s next for our database. Pat Helland and Daniel May finished Day 1 with a closing keynote on “Yours, Mine, and Ours,” which was all about set reconciliation in the distributed world. This is one of those topics that sounds niche, but sits at the core of correctness at scale. When systems diverge – and they always do – then reconciliation becomes the real problem, not replication. Pat is a legend in this space and his writing at https://pathelland.substack.com/ expands on many of these ideas. Day 2 Day 2 got off to an early start with a pre-show lounge hosted by Tzach Livyatan and Attila Toth sharing tips for getting started with ScyllaDB. The opening keynote from Avi Kivity went deep into the mechanics behind ScyllaDB tablets, with the kind of under-the-hood engineering that makes extreme scale tractable rather than theoretical. I then had the opportunity to host Camille Fournier, joining remotely for a live session on engineering leadership and platform strategy under increasing system complexity. AI was a recurring theme, but the sharper takeaway was how platform teams need to evolve their role as abstraction layers become more dynamic and less predictable. Camille also stayed on for a live Q&A, engaging directly with the audience on both leadership and the practical realities of operating modern platforms at scale. Big thanks to Camille! The next block shifted back into deep technical content, starting with Dominik Tornow from Resonate HQ, sharing a first-principles approach to agentic systems. Alex Dathskovsky followed with a forward-looking session on the future of data consistency in ScyllaDB, reframing consistency not as a static tradeoff but as something increasingly adaptive and workload-aware. Szymon Wasik went deep on ScyllaDB vector search internals with real-time performance at billion-vector scale. It was great to see how ScyllaDB avoids the typical latency cliffs seen in ANN systems. From LinkedIn, Satya Lakshmikanth shared practical lessons from operating large-scale data systems in production, grounding the conversation in real-world constraints. Asias He showed us how incremental repair for ScyllaDB tablets is much more operationally feasible without the traditional overhead around consistency. We also heard from Tyler Denton, showcasing ScyllaDB vector search in action across two use cases (RAG with Hybrid Memory and anomaly detection at scale). Before lunch, another top quality keynote from TigerBeetle’s Joran Dirk Greef who had plenty of quotable quotes in his talk, “You Can’t Scale When You’re Dead.” And crowd favorite antirez from Redis gave us his take on HNSW indexes and all the tradeoffs that need to be considered. The final block in an already monster-sized conference followed up with Teiva Harsanyi from Google, sharing lessons drawn from large-scale distributed systems like Gemini. MoEngage brought a practitioner view on operating high-throughput, user-facing systems where latency directly impacts engagement. Benny Halevy outlined the path to tiered storage on ScyllaDB. Rivian discussed real-world automotive data platforms and Brian Jones from SAS highlighted how they tackled tension between batch and realtime workloads at scale by applying ScyllaDB. I also enjoyed the AWS talk from KT Tambe with Tzach Livyatan, tying cloud infrastructure back to database design decisions with the I8g family. To wrap the conference, we heard from Brendan Cox on how Sprig simplified their database infrastructure and achieved predictable low latency with – I’m sure you’ve guessed by now – ScyllaDB. Throughout the event, attendees could also binge-watch talks in Instant Access, which featured gems from Martin Kleppmann and Chris Ricommini, Disney/Hulu, DBOS, Tiket, and more. Prepare for Takeoff Final call to board my monstrous 15-hour flight home… It’s a great privilege to host these virtual conferences live backed by the team at ScyllaDB. The quality of this event ultimately comes down to the people – both the presenters who bring great depth and detail and the audience that keeps the conversation engaged and interesting. Thanks to everyone who contributed to making this the best Monster SCALE Summit to date. Catch up on what you missed If you want to chat with our engineers about how ScyllaDB might work with your use case, book a technical strategy session.

Announcing ScyllaDB Operator, with Red Hat OpenShift Certification

19 March 2026, 1:00 pm by ScyllaDB

OpenShift users gain a trusted, validated path for installing and managing ScyllaDB Operator – backed by enterprise-grade support ScyllaDB Operator is an open-source project that helps you run ScyllaDB on Kubernetes by managing ScyllaDB clusters deployed to Kubernetes and automating tasks related to operating a ScyllaDB cluster. For example, it automates installation, vertical and horizontal scaling, as well as rolling upgrades. The latest release (version 1.20) is now Red Hat certified and available directly in the Red Hat OpenShift ecosystem catalog. Additionally, it brings new features, stability improvements and documentation updates. Red Hat OpenShift Certification and Catalog Availablity OpenShift has become a cornerstone platform for enterprise Kubernetes deployments, and we’ve been working to ensure ScyllaDB Operator feels like a native part of that ecosystem. With ScyllaDB Operator 1.20, we’re taking a significant step forward: the operator is now Red Hat certified and available directly in the Red Hat OpenShift ecosystem catalog. See the ScyllaDB Operator project in the Red Hat Ecosystem Catalog. This milestone gives OpenShift users a trusted, validated path for installing and managing ScyllaDB Operator – backed by enterprise-grade support. With this release, you can install ScyllaDB Operator through OLM (Operator Lifecycle Manager) using either the OpenShift Web Console or CLI. For detailed installation instructions and OpenShift-specific configuration examples – including guidance for platforms like Red Hat OpenShift Service on AWS (ROSA) – see the Installing ScyllaDB Operator on OpenShift guide. IPv6 support ScyllaDB Operator 1.20 brings native support for IPv6 and dual-stack networking to your ScyllaDB clusters. With dual-stack support, your ScyllaDB clusters can operate with both IPv4 and IPv6 addresses simultaneously. That provides flexibility for gradual migration scenarios or environments requiring support for both protocols. You can also configure IPv6-first deployments, where ScyllaDB uses IPv6 for internal communication while remaining accessible via both protocols. You can control the IP addressing behaviour of your cluster through v1.ScyllaCluster’s .spec.network. The API abstracts away the underlying ScyllaDB configuration complexity so you can focus on your networking requirements rather than implementation details. With this release, IPv4-first dual-stack and IPv6-first dual-stack configurations are production-ready. IPv6-only single-stack mode is available as an experimental feature under active development; it’s not recommended for production use. See Production readiness for details. Learn more about IPv6 networking in the IPv6 networking documentation. Other notable changes Documentation improvements This release includes a new guide on automatic data cleanups. It explains how ScyllaDB Operator ensures that your ScyllaDB clusters maintain storage efficiency and data integrity by removing stale data and preventing data resurrection. Dependency updates This release also includes regular updates of ScyllaDB Monitoring and the packaged dashboards to support the latest ScyllaDB releases (4.12.1->4.14.0, #3250), as well as its dependencies: Grafana (12.2.0->12.3.2) and Prometheus (v3.6.0->v3.9.1). For more changes and details, check out the GitHub release notes. Upgrade instructions For instructions on upgrading ScyllaDB Operator to 1.20, please refer to the Upgrading ScyllaDB Operator section of the documentation. Supported versions ScyllaDB 2024.1, 2025.1, 2025.3 – 2025.4 Red Hat OpenShift 4.20 Kubernetes 1.32 – 1.35 Container Runtime Interface API v1 ScyllaDB Manager 3.7 – 3.8 Getting started with ScyllaDB Operator ScyllaDB Operator Documentation Learn how to deploy ScyllaDB on Google Kubernetes Engine (GKE) Learn how to deploy ScyllaDB on Amazon Elastic Kubernetes Engine (EKS)  Learn how to deploy ScyllaDB on a Kubernetes Cluster Related links ScyllaDB Operator source (on GitHub) ScyllaDB Operator image on DockerHub ScyllaDB Operator Helm Chart repository ScyllaDB Operator documentation ScyllaDB Operator for Kubernetes lesson in ScyllaDB University Report a problem Your feedback is always welcome! Feel free to open an issue or reach out on the #scylla-operator channel in ScyllaDB User Slack.  

Instaclustr product update: March 2026

19 March 2026, 12:00 pm by Apache Cassandra - Instaclustr

Here’s a roundup of the latest features and updates that we’ve recently released.

If you have any particular feature requests or enhancement ideas that you would like to see, please get in touch with us.

Major announcements Introducing AI Cluster Health: Smarter monitoring made simple

Turn complex metrics into clear, actionable insights with AI-powered health indicators—now available in the NetApp Instaclustr console. The new AI Cluster Health page simplifies cluster monitoring, making it easy to understand your cluster’s state at a glance without requiring deep technical expertise. This AI-driven analysis reviews recent metrics, highlights key indicators, explains their impact, and assigns an easy traffic-light health score for a quick status overview.

NetApp introduces Apache Kafka® Tiered Storage support on GCP in public preview

Tiered Storage is now available in public review for Instaclustr for Apache Kafka on Google Cloud Platform. This feature enables customers to optimize storage costs and improve scalability by offloading older Kafka log segments from local disk to Google Cloud Storage (GCS), while keeping active data local for fast access. Kafka clients continue to consume data seamlessly with no changes required, allowing teams to reduce infrastructure costs, simplify cluster scaling, and extend retention periods for analytics or compliance.

Other significant changes Apache Cassandra®
  • Released Apache Cassandra 4.0.19 and 5.0.6 into general availability on the NetApp Instaclustr Managed Platform, giving customers access to the latest stability, performance, and security improvements.
  • Multi–data center Apache Cassandra clusters can now be provisioned across public and private networks via the Instaclustr Console, API, and Terraform provider, enabling customers to provision multi-DC clusters from day one.
  • Single CA feature is now available for Apache Cassandra clusters. See Single CA for more details.
  • GCP n4 machine types are now supported for Apache Cassandra in the available regions.
Apache Kafka® ClickHouse®
  • ClickHouse 25.8.11 has been added to our managed platform in General Availability.
  • Enabled ClickHouse system.session_log table that plays a key role in tracking session lifecycle and auditing user activities for enhanced session monitoring. This helps you with troubleshooting client-side connectivity issues and provides insights into failed connections.
OpenSearch®
  • OpenSearch 2.19.4 and 3.3.2 have been released to general availability.
  • Added support for the OpenSearch Assistant feature in OpenSearch Dashboards for clusters with Dashboards and AI Search enabled.
PostgreSQL® Instaclustr Managed Platform
  • Added self-service Tags Management feature—allowing users to add, edit, or delete tags for their clusters directly through the Instaclustr console, APIs, or Terraform provider for RIYOA deployments
  • Added new region Germany West Central for Azure
Future releases Apache Kafka®
  • Following the private preview release, Kafka’s Client Telemetry feature is progressing toward general availability soon. Read more here.
ClickHouse®
  • We plan to extend the current ClickHouse integration with FSxN data sources by adding support for deployments across different VPCs, enabling broader enterprise lakehouse architectures.
  • Apache Iceberg and Delta Lake integration are planned to soon be available for ClickHouse on the NetApp Instaclustr Platform, giving you a practical way to run analytics on open table formats while keeping control of your existing data platforms.
  • We plan to soon introduce fully integrated AWS PrivateLink as a ClickHouse Add-On for secure and seamless connectivity with ClickHouse.
PostgreSQL®
  • We’re aiming to launch PostgreSQL integrated with FSx for NetApp ONTAP (FSxN) along with NVMe support into general availability soon. This enhancement is designed to combine enterprise-grade PostgreSQL with FSxN’s scalable, cost-efficient storage, enabling customers to optimize infrastructure costs while improving performance and flexibility. NVMe support is designed to deliver up to 20% greater throughput vs NFS.
OpenSearch®
  • An AI Search plugin for OpenSearch is being released to GA (currently in public preview) to enhance search experiences using AI‑powered techniques such as semantic, hybrid, and conversational search, enabling more relevant, context‑aware results and unlocking new use cases including retrieval‑augmented generation (RAG) and AI‑driven chatbots.
Instaclustr Managed Platform
  • Following the public preview release, Zero Inbound Access is progressing to General Availability, designed to deliver the most secure management connectivity by eliminating inbound internet exposure and removing the need for any routable public IP addresses, including bastion or gateway instances.
Did you know?

If you have any questions or need further assistance with these enhancements to the Instaclustr Managed Platform, please contact us.

SAFE HARBOR STATEMENT: Any unreleased services or features referenced in this blog are not currently available and may not be made generally available on time or at all, as may be determined in NetApp’s sole discretion. Any such referenced services or features do not represent promises to deliver, commitments, or obligations of NetApp and may not be incorporated into any contract. Customers should make their purchase decisions based upon services and features that are currently generally available. 

The post Instaclustr product update: March 2026 appeared first on Instaclustr.

Integrated Gauges: Lessons Learned Monitoring Seastar’s IO Stack

17 March 2026, 12:23 pm by ScyllaDB

Why integrated gauges are a better approach for measuring frequently changing values Many performance metrics and system parameters are inherently volatile or fluctuate rapidly. When using a monitoring system that periodically “scrapes” (polls) a target for its current metric value, the collected data point is merely a snapshot of the system’s state at that precise moment. It doesn’t reveal much about what’s actually happening in that area. Sometimes it’s possible to overcome this problem by accumulating those values somehow – for example, by using histograms or exporting a derived monotonically increasing counter. This article suggests yet another way to extend this approach for a broader set of frequently changing parameters. The Problem with Instantaneous Metrics For rapidly changing values such as queue lengths or request latencies, a single snapshot is most often misleading. If the scrape happens during a peak load, the value will appear high. If it happens during an idle moment, the value will appear low. Over time, the sampled data usually does not accurately represent the system’s true average behavior, leading to misinformed alerting or capacity planning. This phenomenon is apparent when examining synthetically generated data. Take a look at the example below. On that plot, there’s a randomly generated XY series. The horizontal axis represents the event number, the vertical axis represents the frequently fluctuating value. The “value” changes on every event. Fig.1 Random frequently changing data Now let’s thin the data out and see what would happen if we show only every 40th point, as if it were a real monitoring system that captures the value at a notably lower rate. The next plot shows what it would look like. Fig.2 Sampling every 40th point from the data Apparently, this is a very poor approximation of the first plot. It becomes crystal clear how poor it is if we zoom into the range [80-120] of both plots. For the latter (dispersed) plot, we’ll see a couple of dots with values of 2 and 0. But the former (original) plot would reveal drastically different information, shown below. Fig.3 Zoom-in range [80-120] from the data Now remember that the problem revealed itself at the ratio of the real rate to scrape rate being just 40. In real systems, internal parameters may change thousands of times per second while the scrape period is minutes. In that case, you end up scraping less than a fraction of a percent. A better way to monitor the frequently changing data is needed…badly. Histograms Request latency is one example of a statistic that usually contains many data points per second. Histograms can help you see how slow or fast the requests are – without falling into the problem described above. A monitoring histogram is a type of metric that samples observations and counts them in configurable buckets. Instead of recording just a single average or maximum latency value, a histogram provides a distribution of these values over a given period. By analyzing the bucket counts, you can calculate percentiles, including p50 (known as the median value) or p99 (the value below which 99% of all requests fell). This provides a much more robust and actionable view of performance volatility than simple instantaneous gauges or averages. Fig.4 Histogram built from data X-points It’s a static snapshot of the data at the last “time point.” If the values change over time, modern monitoring systems can offer various data views, such as time-series percentiles or heatmaps, to provide the necessary insight into the data. Histograms, however, have a drawback: They require system memory to work, node networking throughput to get reported, and monitoring disk space to be stored. A histogram of N buckets consumes N times more resources than a single value. Addable latencies When it comes to reporting latencies, a good compromise solution between efficiency and informativeness is “counter” metrics coupled with the rate() function. Counters and rates Counter metrics are one of the simplest and most fundamental metric types in the Prometheus monitoring system. It’s a cumulative metric that represents a single monotonically increasing counter whose value can only increase or be reset to zero upon a restart of the monitored target. Because a counter itself is just an ever-increasing total, it is rarely analyzed directly. Instead, one derives another meaningful metric from counters, most notably a “rate”. Below is a mathematical description of how the prometheus rate() function works. Internally, the system calculates the total sum of the observed values. After scraping the value several times, the monitoring system calculates the “rate” function of the value, which takes the total value difference from the previous scrape, divided by the time passed since then. The rated value thus shows the average value over the specified period of time. Now let’s get back to latencies. To report average latency over the scraping period using counters, the system should accumulate two of them: the total sum of request latencies (e.g., in milliseconds) and the total number of completed requests. The monitoring system would then “rate” both counters to get their averages and divide them, thus showing the average per-request latency. It looks like this: Since the total number of requests served is useful on its own to see the IOPS value, this method is as efficient as exporting the immediate latency value. Yet, it provides a much more stable and representative metric than an instantaneous gauge. We can try to adopt counters to the artificial data that was introduced earlier. The plot below shows what the averaged values for the sub-ranges of length 40 (the sampling step from above) would look like. It differs greatly from the sampled plot of Figure 2 and provides a more accurate approximation of the real data set. Fig.5 Average values for sub-ranges of length 40 Of course, this method has its drawbacks when compared to histograms. It swallows latency spikes that last for a short duration, as compared to the scraping period. The shorter the spike duration, the more likely it would go unnoticed. Queue length Summing up individual values is not always possible though. Queue length is another example of a statistic that’s also volatile and may contain thousands of data points. For example, this could be the queue of tasks to be executed or the queue of IO requests. Whenever an entry is added to the queue, its length increases. When an entry is removed, the length decreases – but it makes little sense to add up the updated queue length elsewhere. If we return to Figure 3 showing the real values in the range of [80-120], what would the average queue length over that period be? Apparently, it’s the sum of individual values divided by their number. But even though we understand what the “average request latency” is, the idea of “average queue length” is harder to accept, mainly because the X value of the above data is usually not an “event”, but it’s rather a “time”. And if, for example, a queue was empty most of the time and then changed to N elements for a few milliseconds, we’d have just two events that changed the queue. Seeing the average queue length of N/2 is counterintuitive. Some time ago, we researched how the “real” length of an IO queue can be implicitly derived from the net sum of request latencies. Here, we’ll show another approach to getting an idea of the queue length. Integrated gauge The approach is a generalization of averaging the sum of individual data points from the data set using counters and the “rate” function. Let’s return to our synthetic data when it was summed and rated (Figure 3) and look at the corresponding math from a slightly different angle. If we treat each value point as a bar with the width of 1 and the height being equal to the value itself, we can see that: The total value is the total sum of the bars’ squares The difference between two scraped total values is the sum of squares of bars between two scraping points The number of points in the range equals the distance between those two scraping points Fig.6 Geometrical interpretation of the exported counters Figure 6 shows this area in green. The average value is thus the height of the imaginary rectangular whose width equals the scraping period. If the distance between two adjacent points is not 1, but some duration, the interpretation still works. We can still calculate the square under the plot and divide it by the area width to get its “average” value. But we need to apply two changes. First, the square of the individual bar is now the product of the value itself and the duration of time passed from the previous point. Think of it this way: previously, the duration was 1, so the multiplication was invisible.Now, it is explicit. Second, we no longer need to count the number of points in the range. Instead, the denominator of the averaging function will be the duration between scraping points. In other words, previously the number of points was the sum of 1-s (one-s) between scraping points; now, it’s the sum of durations – total scraping period It’s now clear that the average value is the result of applying the “rate()” function to the total value. Naming problem (a side note) There are two hard problems in computer science: cache invalidation, naming, and off-by-one errors. Here we had to face one of them – how to name the newly introduced metrics? It is the queue size multiplied by the time the queue exists in such a state. A very close analogy comes from project management. There’s a parameter called “human-hour” and it’s widely used to estimate the resources needed to accomplish some task. In physics, there are not many units that measure something multiplied by time. But there are plenty of parameters that measure something divided by time, like velocity (distance-per-second), electric current (charge-per-second) or power (energy-per-second). Even though it’s possible to define (e.g., charge as current multiplied by time), it’s still charge that’s the primary unit and current is secondary. So far I’ve found quite a few examples of such units. In classical physics, one is called “action” and measures energy-times-time, and another one is “impulse,” which is measured in newtons-times-seconds. Finally, in kinematics there’s a thing called “absement,” which is literally meters-times-seconds. That describes the measure of an object displacement from its initial position. Integrated queue length The approach described above was recently [applied] to the Seastar IO stack – the length of IO classes’ request queues was patched to account for and export the integrated value. Below is the screenshot of a dashboard showing the comparison of both compaction class queue lengths, randomly scraped and integrated. Interesting (but maybe hard to accept) are the fraction values of the queue length. That’s OK, since the number shows the average queue length over a scrape period of a few minutes. A notable advantage of the integrated metric can be seen on the bottom two plots that show the length of the in-disk queue. Only the integrated metric (bottom right plot) shows that disk load actually decreased over time, while the randomly scraped one (bottom left plot) just tells us that the disk wasn’t idling…but not more than that. This effect of “hiding” the reality from the observer can also be seen in the plot that shows how the commitlog class queue length was changing over time. Here we can see a clear rectangular “spike” in the integrated disk queue length plot. That spike was completely hidden by the randomly scraped one. Similarly, the software queue length (upper pair of plots) dynamics is only visible from the integrated counter (upper right plot). Conclusion Relying solely on instantaneous metrics, or gauges, to monitor rapidly fluctuating system parameters very often leads to misleading data that poorly reflects the system’s actual behavior over a period of time. While solutions like histograms offer better statistical insights, they incur notable resource overhead. For metrics where the individual values can be aggregated (like request latencies), converting them into cumulative counters and deriving a rate provides a much more stable and representative average over the scraping interval. This offers a very efficient compromise between informative granularity and resource consumption. For metrics where instantaneous values cannot be simply summed (such as queue lengths), the concept of the Integrated Gauge offers a generalization of the same efficiency. In essence, by treating the gauge not as a point-in-time value but as a continuously accumulating measure of time-at-value, integral gauges provide a highly reliable and definitive representation of a parameter’s average behavior across any given measurement interval.

From ScyllaDB to Kafka: Natura’s Approach to Real-Time Data at Scale

9 March 2026, 12:17 pm by ScyllaDB

How Natura built a real-time data pipeline to support orders, analytics, and operations Natura, one of the world’s largest cosmetics companies, relies on a network of millions of beauty consultants generating a massive amount of orders, events, and business data every day. From an infrastructure perspective, this requires processing vast amounts of data to support orders, campaigns, online KPIs, predictive analytics, and commercial operations. Natura’s Rodrigo Luchini (Software Engineering Manager) and Marcus Monteiro (Senior Engineering Tech Lead) shared the technical challenges and architecture behind these use cases at Monster SCALE Summit 2025. Fitting for the conference theme, they explained how the team powers real-time sales insights at massive scale by building upon ScyllaDB’s CDC Source Connector. About Natura Rodrigo kicked off the talk with a bit of background on Natura. Natura was founded in 1969 by Antônio Luiz Seabra. It is a Brazilian multinational cosmetics and personal care company known for its commitment to sustainability and ethical sourcing. They were one of the first companies to focus on products connected to beauty, health, and self-care. Natura has three core pillars: Sustainability: They are committed to producing products without animal testing and to supporting local producers, including communities in the Amazon rainforest. People: They value diversity and believe in the power of relationships. This belief drives how they work at Natura and is reflected in their beauty consultant network. Technology: They invest heavily in advanced engineering as well as product development. The Technical Challenge: Managing Massive Data Volume with Real-Time Updates The first challenge they face is integrating a high volume of data (just imagine millions of beauty consultants generating data and information every single day). The second challenge is having real-time updated data processing for different consumers across disconnected systems. Rodrigo explained, “Imagine two different challenges: creating and generating real-time data, and at the same time, delivering it to the network of consultants and for various purposes within Natura.” This is where ScyllaDB comes in. Here’s a look at the initial architecture flow, focusing on the order and API flow. As soon as a beauty consultant places an order, they need to update and process the related data immediately. This is possible for three main reasons: As Rodrigo put it, “The first is that ScyllaDB is a fast database infrastructure that operates in a resilient way. The second is that it is a robust database that replicates data across multiple nodes, which ensures data consistency and reliability. The last but not least reason is scalability – it’s capable of supporting billions of data processing operations.” The Natura team architected their system as follows: In addition to the order ingestion flow mentioned above, there’s an order metrics flow closely connected to ScyllaDB Cloud (ScyllaDB’s fully-managed database-as-a-service offering), as well as the ScyllaDB CDC Source Connector (A Kafka source connector capturing ScyllaDB CDC changes). Together, this enables different use cases in their internal systems. For example, it’s used to determine each beauty consultant’s business plan and also to report data across the direct sales network, including beauty consultants, leaders, and managers. These real-time reports drive business metrics up the chain for accurate, just-in-time decisions. Additionally, the data is used to define strategy and determine what products to offer customers. Contributing to the ScyllaDB CDC Source Connector When Natura started testing the ScyllaDB Connector, they noticed a significant spike in the cluster’s resource consumption. This continued until the CDC log table was fully processed, then returned to normal. At that point, the team took a step back. After reviewing the documentation, they learned that the connector operates with small windows (15 seconds by default) for reading the CDC log tables and sending the results to Kafka. However, at startup, these windows are actually based on the table TTL, which ranged from one to three days in Natura’s use case. Marcus shared: “Now imagine the impact. A massive amount of data, thousands of partitions, and the database reading all of it and staying in that state until the connector catches up to the current time window. So we asked ourselves: ‘Do we really need all the data?’ No. We had already run a full, readable load process for the ScyllaDB tables. What we really needed were just incremental changes, not the last three days, not the last 24 hours, just the last 15 minutes.” So, as ScyllaDB was adding this feature to the GitHub repo, the Natura team created a new option: scylla.custom.window.start. This let them tell the connector exactly where to start, so they could avoid unnecessary reads and relieve unnecessary load on the database. Marcus wrapped up the talk with the payoff: “This results in a highly efficient real-time data capture system that streams the CDC events straight to Kafka. From there, we can do anything—consume the data, store it, or move it to any database. This is a gamechanger. With this optimization, we unlocked a new level of efficiency and scalability, and this made a real difference for us.”

Claude Code Marketplace Now Available

19 February 2026, 12:00 am by Posts on RustyRazorblade Consulting

Claude Code has become an indispensable part of my daily workflow. I use it for everything from writing code to debugging production issues. But while Claude is incredibly capable out of the box, there are areas where injecting specialized domain knowledge makes it dramatically more useful.

That’s why I built a plugin marketplace. Yesterday I released rustyrazorblade/skills, a collection of Claude Code plugins that extend Claude with expert-level knowledge in specific domains. The first plugin is something I’ve been talking about doing for a while: a Cassandra expert.

Apache Cassandra® 5.0: Improving performance with Unified Compaction Strategy

16 February 2026, 5:49 pm by Apache Cassandra - Instaclustr

Introduction

Unified Compaction Strategy (UCS), introduced in Apache Cassandra 5.0, is a versatile compaction framework that not only unifies the benefits of Size-Tiered (STCS) and Leveled (LCS) Compaction Strategies, but also introduces new capabilities like shard parallelism, density-aware SSTable organization, and safer incremental compaction, all of which deliver more predictable performance at scale. By utilizing a flexible scaling model, UCS allows operators to tune compaction behavior to match evolving workloads, spanning from write-heavy to read-heavy, without requiring disruptive strategy migrations in most cases.

In the past, operators had to choose between rigid strategies and accept significant trade-offs. UCS changes this paradigm, allowing the system to efficiently adapt to changing workloads with tuneable configurations that can be altered mid-flight and even applied differently across different compaction levels based on data density.

Why compaction matters

Compaction is the critical process that determines a cluster’s long-term health and cost-efficiency. When executed correctly, it produces denser nodes with highly organized SSTables, allowing each server to store more data without sacrificing speed. This efficiency translates to a smaller infrastructure footprint, which can lower cloud costs and resource usage.

Conversely, inefficient compaction is a primary driver of performance degradation. Poorly managed SSTables lead to fragmented data, forcing the system to work harder for every request. This overhead consumes excessive CPU and I/O, often forcing teams to try adding more nodes (horizontal scale) just to keep up with background maintenance noise.

Key concepts and terminology

To understand how UCS optimizes a cluster, it is necessary to understand the fundamental trade-offs it balances:

  • Read amplification: Occurs when the database must consult multiple SSTables to answer a single query. High read amplification acts as a “latency tax,” forcing extra I/O to reconcile data fragments.
  • Write amplification: A metric that quantifies the overhead of background processes (such as compactions). It represents the ratio between total data written to disk and the amount of data originally sent by an application. High write amplification wears out SSDs and steals throughput.
  • Space amplification: The ratio of disk space used to the actual size of the “live” data. It tracks data such as tombstones or overwritten rows that haven’t been purged yet.
  • Fan factor: The “growth dial” for the cluster data hierarchy. It defines how many files of a similar size must accumulate before they are merged into a larger tier.
  • Sharding: UCS splits data into smaller, independent token ranges (shards), allowing the system to run multiple compactions in parallel across CPU cores.
Performance gains by design

UCS provides baseline architectural improvements that were not available in older strategies:

Improved compaction parallelism

Older strategies often got stuck on a single thread during large merges. UCS sharding allows a server to use its full processing power. This significantly reduces the likelihood of compaction storms and keeps tail latencies (p99) predictable.

Reduced disk space amplification

Because UCS operates on smaller shards, it doesn’t need to double the entire disk space of a node to perform a major merge. This greatly reduces the risk of nodes from running out of space during heavy maintenance cycles.

Density-based SSTable organization

UCS measures SSTables by density (token range coverage). This mitigates the huge SSTable problem where a single massive file becomes too large to compact, hindering read performance indefinitely.

Scaling parameter

The scaling parameter (denoted as W) is a configurable setting that determines the size ratio between compaction tiers. It helps balance write amplification and read performance by controlling how much data is rewritten during compaction operations. A lower scaling parameter value results in more frequent, smaller compactions, whereas a higher value leads to larger compaction groups.

The strategy engine: tuning and parameters

UCS acts as a strategy engine by adjusting the scaling parameter (W), allowing UCS to mimic, or outperform, its predecessors STCS and LCS.

At a high level, the scaling parameter influences the effective fan-out behavior at each compaction level. Tiered-style settings such as T4 allow more SSTables to accumulate before merging, favoring write efficiency, while leveled-style settings such as L10 keep SSTables more tightly organized, reducing read amplification at the cost of additional background work.

The numbers below are illustrative and not prescriptive:

UCS configuration guide Workload type Strategy target Scaling (W) Primary benefit Heavy writes / IoT STCS (Tiered) Negative   (e.g., -4) Lowest read amplification Heavy reads LCS (Leveled) Positive      (e.g., 10) Lowest write amplification Balanced Hybrid Zero (0) Balanced performance for general apps Practical example

UCS allows operators to mix behaviors across the data lifecycle.

'scaling_parameters': 'T4, T4, L10'

Note that scaling_parameters takes a string format that can accommodate parameters for per-level tuning.

This example instructs a cluster: “Use tiered compaction for the first two levels to keep up with the high write volume, but once data reaches the third level, reorganize it into a leveled structure so reads stay fast.”

Here’s a fuller, illustrative example of how one might structure their CQL to change the compaction strategy.

ALTER TABLE keyspace_name.table_name   WITH compaction = {  'class': 'UnifiedCompactionStrategy',  'scaling_parameters': 'T4,T4,L10'   };
Operational evolution: moving beyond major compactions

In older strategies and in Apache Cassandra versions prior to 5.0, operators often felt forced to run a major compaction to reclaim disk space or fix performance. This was a critical event that could impact a node’s I/O for extended periods of time and required substantial free disk space to complete.

Because UCS is density-aware and sharded, it effectively performs compactions constantly and granularly so major compactions are rarely needed. It identifies overlapping data within specific token ranges (shards) and cleans them up incrementally. Operators no longer must choose between a fragmented disk and a risky, resource-heavy manual compaction; UCS keeps data density more uniform across the cluster over time.

The migration advantage: “in-place” adoption

One of the key performance features of a UCS migration is in-place adoption, meaning that when a table is switched to UCS, it does not immediately force a massive data rewrite. Instead, it looks at the existing SSTables, calculates their density, and maps them into its new sharding structure.

This allows for moving from STCS or LCS to UCS with significantly less I/O overhead than any other strategy change.

Conclusion

UCS is an operational shift toward simplicity and predictability. By removing the need to choose between compaction trade-offs, UCS allows organizations to scale with confidence. Whether handling a massive influx of IoT data or serving high-speed user profiles, UCS helps clusters remain performant, cost-effective, and ready for the future.

On a newly deployed NetApp Instaclustr Apache Cassandra 5 cluster, UCS is already the default strategy (while Apache Cassandra 5.0 has STCS set as the default).

Ready to experience this new level of Cassandra performance for yourself? Try it with a free 30-day trial today!

The post Apache Cassandra® 5.0: Improving performance with Unified Compaction Strategy appeared first on Instaclustr.

Exploring the key features of Cassandra® 5.0

14 January 2026, 12:00 pm by Apache Cassandra - Instaclustr

Apache Cassandra has become one of the most broadly adopted distributed databases for large-scale, highly available applications since its launch as an open source project in 2008. The 5.0 release in September 2024 represents the most substantial advancement to the project since 4.0 released in July 2021. Multiple customers (and our own internal Cassandra use case) have now been happily running on Cassandra 5 for up to 12 months so we thought the time was right to explore the key features they are leveraging to power their modern applications.

An overview of new features in Apache Cassandra 5.0

Apache Cassandra 5.0 introduces core capabilities aimed at AI-driven systems, low-latency analytical workloads, and environments that blend operational and analytical processing. 

Highlights include: 

  • The new vector data type and an Approximate Nearest Neighbor (ANN) index based on Hierarchical Navigable Small World (HNSW), which is integrated into the Storage-Attached Index (SAI) architecture
  • Trie-based memtables and the Big Trie-Index (BTI) SSTable format, delivering better memory efficiency and more consistent write performance
  • The Unified Compaction Strategy, a tunable density-based approach that can align with leveled or tiered compaction patterns. 

Additional enhancements include expanded mathematical CQL functions, dynamic data masking, and experimental support for Java 17.

At NetApp, Apache Cassandra 5.0 is fully supported, and we are actively assisting customers as they transition from 4.x.

A deeper look at Cassandra 5.0’s key features Storage–Attached Indexes (SAI)

Storage–Attached Indexes bring a modern, storage-integrated approach to secondary indexing in Apache Cassandra, resolving many of the scalability and maintenance challenges associated with earlier index implementations. Legacy Secondary Indexes (2i) and SASI remain available, but SAI offers a more robust and predictable indexing model for a broad range of production workloads.

SAI operates per-SSTable, allowing queries to be indexed locally versus the cluster-wide coordination required of other strategies. This model supports diverse CQL data types, enables efficient numeric and text range filters, and provides more consistent performance characteristics than 2i or SASI. The same storage-attached foundation is also used for Cassandra 5’s vector indexing mechanism, allowing ANN search to operate within the same storage and query framework.

SAI supports combining filters across multiple indexed columns and works seamlessly with token-aware routing to reduce unnecessary coordinator work. Public evaluations and community testing have shown faster index builds, more predictable read paths, and improved disk utilization compared with previous index formats.

Operationally, SAI functions as part of the storage engine itself: indexes are defined using standard CQL statements and are maintained automatically during flush and compaction, with no cluster-wide rebuilds required. This provides more flexible query options and can simplify application designs that previously relied on manual denormalization or external indexing systems.

Native Vector Search capabilities

Apache Cassandra 5.0 introduces native support for high-dimensional vector embeddings through the new vector data type. Embeddings represent semantic information in numerical form, enabling similarity search to be performed directly within the database. The vector type is integrated with the database’s storage-attached index architecture, which uses HNSW graphs to efficiently support ANN search across cosine, Euclidean, and dot-product similarity metrics.

With vector search implemented at the storage layer, applications involving semantic matching, content discovery, and retrieval-oriented workflows while maintaining the system’s established scalability and fault-tolerance characteristics are supported.

After upgrading to 5.0, existing schemas can add vector columns and store embeddings through standard write operations. For example:

UPDATE products SET embedding = [0.1, 0.2, 0.3, 0.4, 0.5] WHERE id = <id>;

To create a new table with a vector type column:

CREATE TABLE items (     product_id UUID PRIMARY KEY,     embedding VECTOR<FLOAT, 768>  // 768 denotes dimensionality );

Because vector indexes are attached to SSTables, they participate automatically in the compaction and repair processes and do not require an external indexing system. ANN queries can be combined with regular CQL filters, allowing similarity searches and metadata conditions to be evaluated within a unified distributed query workflow. This brings vector retrieval into Apache Cassandra’s native consistency, replication, and storage model.

Unified Compaction Strategy (UCS)

Unified Compaction Strategy in Apache Cassandra 5 included a density-aware approach to organizing SSTables that blends the strengths of Leveled Compaction Strategy (LCS) and Size Tiered Compaction Strategy (STCS). UCS aims to provide the predictable read amplification associated with LCS and the write efficiency of STCS, without many of the workload-specific drawbacks that previously made compaction selection difficult. Choosing an unsuitable compaction strategy in earlier releases could lead to operational complexity and long-term performance issues, which UCS is designed to mitigate.

UCS exposes a set of tunable parameters like density thresholds and per-level scaling that let operators adjust compaction behavior toward read-heavy, write-heavy, or time-series patterns. This flexibility also helps smooth the transition from existing strategies, as UCS can adopt and improve the current SSTable layout without requiring a full rewrite in most cases. The introduction of compaction shards further increases parallelism and reduces the impact of large compactions on cluster performance.

Although LCS and STCS remain available (and while STCS remains the default strategy in 5.0, UCS is the default strategy on newly deployed NetApp Instaclustr’s managed Apache Cassandra 5 clusters), UCS supports a broader range of workloads, reduces the operational burden of compaction tuning, and aligns well with other storage engine improvements in Apache Cassandra 5 such as trie-based SSTables and Storage-Attached Indexes. 

Trie Memtables and Trie-Indexed SSTables

Trie Memtables and Trie-indexed SSTables (Big Trie-Index, BTI) are significant storage engine enhancements released in Apache Cassandra 5. They are designed to reduce memory overhead, improve lookup performance, and increase flush efficiency. A trie data structure stores keys by shared prefixes instead of repeatedly storing full keys, which lowers object count and improves CPU cache locality compared with the legacy skip-list memtable structure. These benefits are particularly visible in high-ingestion, IoT, and time-series workloads.

Skip-list memtables store full keys for every entry, which can lead to large heap usage and increased garbage collection activity under heavy write loads. Trie Memtables substantially reduce this overhead by compacting key storage and avoiding pointer-heavy layouts. On disk, the BTI SSTable format replaces the older BIG index with a trie-based partition index that removes redundant key material and reduces the number of key comparisons needed during partition lookups.

Using Trie memtables requires enabling both the trie-based memtable implementation and the BTI SSTable format. Existing BIG SSTables are converted to BTI through normal compaction or by rebuilding data. On NetApp Instaclustr’s managed Apache Cassandra clusters Trie Memtables and BTI are enabled by default, but when upgrading major versions to 5.0, data must be converted from BIG to BTI first to utilize Trie structures.

Other new features Mathematical CQL functions

Apache Cassandra 5.0 added a rich set of math functions allowing developers to perform computations directly within queries. This reduces data transfer overhead and reduces client-side post-processing, among many other benefits. From fundamental functions like ABS(), ROUND(), or SQRT() to more complex operations like SIN(), COS(), TAN(), these math functions are extensible to a multitude of domains from financial data, scientific measurements or spatial data.

Dynamic Data Masking

Dynamic Data Masking (DDM) is a new feature to obscure sensitive column-level data at query time or permanently attach the functionality to a column so that the data always returns obfuscated. Stored data values are not altered in this process, and administrators can control access through role-based access control (RBAC) to ensure only those with access can see the data while also tuning the visibility of the obscured data. This feature helps with adherence to data privacy regulations such as GDPR, HIPAA, and PCI DSS without needing external redaction systems.

Conclusion

Apache Cassandra 5.0 packs a punch with game changing features that meet the needs of modern workloads and applications. Features like vector search capabilities and Storage Attached Indexes stand out as they will inevitably shape how data can be leveraged within the same database while maintaining speed, scale, and resilience. 

When you deploy a managed cluster on NetApp Instaclustr’s Managed Platform, you get the benefits of all these amazing features without worrying about configuration and maintenance.

Ready to experience the power of Apache Cassandra 5.0 for yourself? Try it free for 30 days today!

The post Exploring the key features of Cassandra® 5.0 appeared first on Instaclustr.

Instaclustr product update: December 2025

18 December 2025, 1:00 pm by Apache Cassandra - Instaclustr

Instaclustr product update: December 2025

Here’s a roundup of the latest features and updates that we’ve recently released.

If you have any particular feature requests or enhancement ideas that you would like to see, please get in touch with us.

Major announcements OpenSearch®

AI Search for OpenSearch®: Unlocking next-generation search

AI Search for OpenSearch, which is now available in Public Preview on the NetApp Instaclustr Managed Platform, is designed to bring semantic, hybrid, and multimodal search capabilities to OpenSearch deployments—turning them into an end-to-end AI-powered search solution within minutes. With built-in ML models, vector indexing, and streamlined ingestion pipelines, next-generation search can be enabled in minutes without adding operational complexity. This feature powers smarter, more relevant discovery experiences backed by AI—securely deployed across any cloud or on-premises environment.

ClickHouse®

FSx for NetApp ONTAP and Managed ClickHouse® integration is now available
We’re excited to announce that NetApp has introduced seamless integration between Amazon FSx for NetApp ONTAP and Instaclustr Managed ClickHouse, to enable customers to build a truly hybrid lakehouse architecture on AWS. This integration is designed to deliver lightning-fast analytics without the need for complex data movement, while leveraging FSx for ONTAP’s unified file and object storage, tiered performance, and cost optimization. Customers can now run zero-copy lakehouse analytics with ClickHouse directly on FSx for ONTAP data—to simplify operations, accelerate time-to-insight, and reduce total cost of ownership.

PostgreSQL®

Instaclustr for PostgreSQL® on Amazon FSx for ONTAP: A new era
We’re excited to announce the public preview of Instaclustr Managed PostgreSQL integrated with Amazon FSx for NetApp ONTAP—combining enterprise-grade storage with world-class open source database management. This integration is designed to deliver higher IOPS, lower latency, and advanced data management without increasing instance size or adding costly hardware. Customers can now run PostgreSQL clusters backed by FSx for ONTAP storage, leveraging on-disk compression for cost savings and paving the way for ONTAP-powered features, such as instant snapshot backups, instant restores, and fast forking. These ONTAP-enabled features are planned to unlock huge operational benefits and will be launched with our GA release.

Other significant changes Apache Cassandra®
  • Transitioned Apache Cassandra v4.1.8 to CLOSED lifecycle state; scheduled to reach End of Life (EOL) on December 20, 2025.
Apache Kafka®
  • Kafka on Azure now supports v5 generation nodes, available in General Availability.
  • Instaclustr Managed Apache ZooKeeper has moved from General Availability to closed status.
ClickHouse
  • Kafka Table Engine integration with ClickHouse has added support to enable real-time data ingestion, streamline streaming analytics, and accelerate insights.
  • New ClickHouse node sizes, powered by AWS m7g, r7i, and r7g instances, are now in Limited Availability for cluster creation.
Cadence®
  • Cadence is now available to be provisioned with Cassandra 5.x, designed to deliver improved performance, enhanced scalability, and stronger security for mission-critical workflows.
OpenSearch PostgreSQL
  • Added new PostgreSQL metrics for connect states and wait event types.
  • PostgreSQL Load Balancer add-on is now available, providing a unified endpoint for cluster access, simplifying failover handling, and ensuring node health through regular checks.
Upcoming releases Apache Cassandra
  • We’re working on enabling multi-datacenter (multi-DC) cluster provisioning via API and console, designed to make it easier to deploy clusters across regions with secure networking and reduced manual steps.
Apache Kafka
  • We’re working on adding Kafka Tiered Storage for clusters running in GCP— designed to bring affordable, scalable retention, and instant access to historical data, to ensure flexibility and performance across clouds for enterprise Kafka users.
ClickHouse
  • We’re planning to extend our Managed ClickHouse to allow it to work with on-prem deployments.
PostgreSQL
  • Following the success of our public preview, we’re preparing to launch PostgreSQL integrated with FSx for NetApp ONTAP (FSxN) into General Availability. This enhancement is designed to combine enterprise-grade PostgreSQL with FSxN’s scalable, cost-efficient storage, enabling customers to optimize infrastructure costs while improving performance and flexibility.
OpenSearch®
  • As part of our ongoing advancements in AI for OpenSearch, we are planning to enable adding GPU nodes into OpenSearch clusters, aiming to enhance the performance and efficiency of machine learning and AI workloads.
Instaclustr Managed Platform
  • Self-service Tags Management feature—allowing users to add, edit, or delete tags for their clusters directly through the Instaclustr console, APIs, or Terraform provider for RIYOA deployments.
Did you know?
  • Cadence Workflow, the open source orchestration engine created by Uber, has officially joined the Cloud Native Computing Foundation (CNCF) as a Sandbox project. This milestone ensures transparent governance, community-driven innovation, and a sustainable future for one of the most trusted workflow technologies in modern microservices and agentic AI architectures. Uber donates Cadence Workflow to CNCF: The next big leap for the open source project—read the full story and discover what’s next for Cadence.
  • Upgrading ClickHouse® isn’t just about new features—it’s essential for security, performance, and long-term stability. In ClickHouse upgrade: Why staying updated matters, you’ll learn why skipping upgrades can lead to technical debt, missed optimizations, and security risks. Then, explore A guide to ClickHouse® upgrades and best practices for practical strategies, including when to choose LTS releases for mission-critical workloads and when stable releases make sense for fast-moving environments.
  • Our latest blog, AI Search for OpenSearch®: Unlocking next-generation search, explains how this new solution enables smarter discovery experiences using built-in ML models, vector embeddings, and advanced search techniques—all fully managed on the NetApp Instaclustr Platform. Ready to explore the future of search? Read the full article and see how AI can transform your OpenSearch deployments.

If you have any questions or need further assistance with these enhancements to the Instaclustr Managed Platform, please contact us.

SAFE HARBOR STATEMENT: Any unreleased services or features referenced in this blog are not currently available and may not be made generally available on time or at all, as may be determined in NetApp’s sole discretion. Any such referenced services or features do not represent promises to deliver, commitments, or obligations of NetApp and may not be incorporated into any contract. Customers should make their purchase decisions based upon services and features that are currently generally available.

The post Instaclustr product update: December 2025 appeared first on Instaclustr.

Freezing streaming data into Apache Iceberg™—Part 1: Using Apache Kafka®Connect Iceberg Sink Connector

16 December 2025, 1:00 pm by Apache Cassandra - Instaclustr

Introduction 

Ever since the first distributed system—i.e. 2 or more computers networked together (in 1969)—there has been the problem of distributed data consistency: How can you ensure that data from one computer is available and consistent with the second (and more) computers? This problem can be uni-directional (one computer is considered the source of truth, others are just copies), or bi-directional (data must be synchronized in both directions across multiple computers). 

Some approaches to this problem I’ve come across in the last 8 years include Kafka Connect (for elegantly solving the heterogeneous many-to-many integration problem by streaming data from source systems to Kafka and from Kafka to sink systems, some earlier blogs on Apache Camel Kafka Connectors and a blog series on zero-code data pipelines), MirrorMaker2 (MM2, for replicating Kafka clusters, a 2 part blog series), and Debezium (Change Data Capture/CDC, for capturing changes from databases as streams and making them available in downstream systems, e.g. for Apache Cassandra and PostgreSQL)—MM2 and Debezium are actually both built on Kafka Connect.  

Recently, some “sink” systems have been taking over responsibility for streaming data from Kafka into themselves, e.g. OpenSearch pull-based ingestion (c.f. OpenSearch Sink Connector), and the ClickHouse Kafka Table Engine (c.f. ClickHouse Sink Connector). These “pull-based” approaches are potentially easier to configure and don’t require running a separate Kafka Connect cluster and sink connectors, but some downsides may be that they are not as reliable or independently scalable, and you will need to carefully monitor and scale them to ensure they perform adequately.  

And then there’s “zero-copy” approaches—these rely on the well-known computer science trick of sharing a single copy of data using references (or pointers), rather than duplicating the data. This idea has been around for almost as long as computers, and is still widely applicable, as we’ll see in part 2 of the blog. 

The distributed data use case we’re going to explore in this 2-part blog series is streaming Apache Kafka data into Apache Iceberg, or “Freezing streaming Apache Kafka data into an (Apache) Iceberg”! In part 1 we’ll introduce Apache Iceberg and look at the first approach for “freezing” streaming data using the Kafka Connect Iceberg Sink Connector. 

What is Apache Iceberg? 

Apache Iceberg is an open source specification open table format optimized for column-oriented workloads, supporting huge analytic datasets. It supports multiple different concurrent engines that can insert and query table data using SQL—and Iceberg is organized like, well, an iceberg! 

The tip of the Iceberg is the Catalog. An Iceberg Catalog acts as a central metadata repository, tracking the current state of Iceberg tables, including their names, schemas, and metadata file locations. It serves as the “single source of truth” for a data Lakehouse, enabling query engines to find the correct metadata file for a table to ensure consistent and atomic read/write operations.  

Just under the water, the next layer is the metadata layer. The Iceberg metadata layer tracks the structure and content of data tables in a data lake, enabling features like efficient query planning, versioning, and schema evolution. It does this by maintaining a layered structure of metadata files, manifest lists, and manifest files that store information about table schemas, partitions, and data files, allowing query engines to prune unnecessary files and perform operations atomically. 

The data layer is at the bottom. The Iceberg data layer is the storage component where the actual data files are stored. It supports different storage backends, including cloud-based object storage like Amazon S3 or Google Cloud Storage, or HDFS. It uses file formats like Parquet or Avro. Its main purpose is to work in conjunction with Iceberg’s metadata layer to manage table snapshots and provide a more reliable and performant table format for data lakes, bringing data warehouse features to large datasets. 

As shown in the above diagram, Iceberg supports multiple different engines, including Apache Spark and ClickHouse. Engines provide the “database” features you would expect, including:  

  • Data Management 
  • ACID Transactions 
  • Query Planning and Optimization 
  • Schema Evolution 
  • And more! 

I’ve recently been reading an excellent book on Apache Iceberg (“Apache Iceberg: The Definitive Guide”), which explains the philosophy, architecture and design, including operation, of Iceberg. For example, it says that it’s best practice to treat data lake storage as immutable—data should only be added to a Data Lake, not deleted.  So, in theory at least, writing infinite, immutable Kafka streams to Iceberg should be straightforward!  

But because it’s a complex distributed system (which looks like a database from above water but is really a bunch of files below water!), there is some operational complexity. For example, it handles change and consistency by creating new snapshots for every modification, enabling time travel, isolating readers from writes, and supporting optimistic concurrency control for multiple writers. But you need to manage snapshots (e.g. expiring old snapshots). And chapter 4 (performance optimisation) explains that you may need to worry about compaction (reducing too many small files), partitioning approaches (which can impact read performance), and handling row-level updates. The first two issues may be relevant for Kafka, but probably not the last one.  So, it looks like it’s good fit for the streaming Kafka use cases, but we may need to watch out for Iceberg management issues.  

“Freezing” streaming data with the Kafka Iceberg Sink Connector 

But Apache Iceberg is “frozen”—what’s the connection to fast-moving streaming data? You certainly don’t want to collide with an iceberg from your speedy streaming “ship”—but you may want to freeze your streaming data for long-term analytical queries in the future. How can you do that without sinking? Actually, a “sink” is the first answer: A Kafka Connect Iceberg Sink Connector is the most common way of “freezing” your streaming data in Iceberg!  

Kafka Connect is the standard framework provided by Apache Kafka to move data from multiple heterogeneous source systems to multiple heterogeneous sink systems, using:  

  • A Kafka cluster 
  • A Kafka Connect cluster (running connectors) 
  • Kafka Connect source connectors 
  • Kafka topics and 
  • Kafka Connect Sink Connectors 

That is, a highly decoupled approach. It provides real-time data movement with high scalability, reliability, error handling and simple transformations.   

Here’s the Kafka Connect Iceberg Sink Connector official documentation

It appears to be reasonably complicated to configure this sink connector; you will need to know something about Iceberg. For example, what is a “control topic”? It’s apparently used to coordinate commits for exactly-once semantics (EOS).  

The connector supports fan-out (writing to multiple Iceberg tables from one topic), fan-in (writing to one Iceberg table from multiple topics), static and dynamic routing, and filtering.  

In common with many technologies that you may want to use as Kafka Connect sinks, they may not all have good support for Kafka metadata. The KafkaMetadata Transform (which injects topic, partition, offset and timestamp properties) is only experimental at present.  

How are Iceberg tables created with the correct metadata? If you have JSON record values, then schemas are inferred by default (but may not be correct or optimal). Alternatively, explicit schemas can be included in-line or referenced from a Kafka Schema Registry (e.g. Karapace), and, as an added bonus, schema evolution is supported.  Also note that Iceberg tables may have to be manually created prior to use if your Catalog doesn’t support table auto-creation.  

From what I understood about Iceberg, to use it (e.g. for writes), you need support from an engine (e.g. to add raw data to the Iceberg warehouse, create the metadata files, and update the catalog).  How does this work for Kafka Connect? From this blog I discovered that the Kafka Connect Iceberg Sink connector is functioning as an Iceberg engine for writes, so there really is an engine, but it’s built into the connector.  

As is the case with all Kafka Connect Sink Connectors, records are available immediately they are written to Kafka topics by Kafka producers and Kafka Connect Source Connectors, i.e. records in active segments can be copied immediately to sink systems. But is the Iceberg Sink Connector real-time? Not really! The default time to write to Iceberg is every 5 minutes (iceberg.control.commit.interval-ms) to prevent multiplication of small files—something that Iceberg(s) doesn’t/don’t like (“melting”?). In practice, it’s because every data file must be tracked in the metadata layer, which impacts performance in many ways—proliferation of small files is typically addressed by optimization and compaction (e.g. Apache Spark supports Iceberg management, including these operations). 

So, unlike most Kafka Connect sink connectors, which write as quickly as possible, there will be lag before records appear in Iceberg tables (“time to freeze” perhaps)!  

The systems are separate (Kafka and Iceberg are independent), records are copied to Iceberg, and that’s it! This is a clean separation of concerns and ownership. Kafka owns the source data (with Kafka controlling data lifecycles, including record expiry), Kafka Connect Iceberg Sink Connector performs the reading from Kafka and writing to Iceberg, and is independently scalable to Kafka. Kafka doesn’t handle any of the Iceberg management.  Once the data has landed in Iceberg, Kafka has no further visibility or interest in it. And the pipeline is purely one way, write only – reads or deletes are not supported.  

Here’s a summary of this approach to freezing streams:  

  1. Kafka Connect Iceberg Sink Connector shares all the benefits of the Kafka Connect framework, including scalability, reliability, error handling, routing, and transformations.  
  2. At least, JSON values are required, ideally full schemas and referenced in Karapace—but not all schemas are guaranteed to work. 
  3. Kafka Connect doesn’t “manage” Iceberg (e.g. automatically aggregate small files, remove snapshots, etc.) 
  4. You may have to tune the commit interval – 5 minutes is the default. 
  5. But it does have a built-in engine that supports writing to Iceberg. 
  6. You may need to use an external tool (e.g. Apache Spark) for Iceberg management procedures. 
  7. It’s write-only to Iceberg. Reads or deletes are not supported 

But what’s the best thing about the Kafka Connect Iceberg Sink Connector? It’s available now (as part of the Apache Iceberg build) and works on the NetApp Instaclustr Kafka Connect platform as a “bring your own connector”  (instructions here).  

In part 2, we’ll look at Kafka Tiered Storage and Iceberg Topics! 

The post Freezing streaming data into Apache Iceberg™—Part 1: Using Apache Kafka®Connect Iceberg Sink Connector appeared first on Instaclustr.

Stay ahead with Apache Cassandra®: 2025 CEP highlights

8 December 2025, 12:00 pm by Apache Cassandra - Instaclustr

Apache Cassandra® committers are working hard, building new features to help you more seamlessly ease operational challenges of a distributed database. Let’s dive into some recently approved CEPs and explain how these upcoming features will improve your workflow and efficiency.

What is a CEP?

CEP stands for Cassandra Enhancement Proposal. They are the process for outlining, discussing, and gathering endorsements for a new feature in Cassandra. They’re more than a feature request; those who put forth a CEP have intent to build the feature, and the proposal encourages a high amount of collaboration with the Cassandra contributors.

The CEPs discussed here were recently approved for implementation or have had significant progress in their implementation.  As with all open-source development, inclusion in a future release is contingent upon successful implementation, community consensus, testing, and approval by project committers.

CEP-42: Constraints framework

With collaboration from NetApp Instaclustr, CEP-42, and subsequent iterations, delivers schema level constraints giving Cassandra users and operators more control over their data. Adding constraints on the schema level means that data can be validated at write time and send the appropriate error when data is invalid.

Constraints are defined in-line or as a separate definition. The inline style allows for only one constraint while a definition allows users to define multiple constraints with different expressions.

The scope of this CEP-42 initially supported a few constraints that covered the majority of cases, but in follow up efforts the expanded list of support includes scalar (>, <, >=, <=), LENGTH(), OCTET_LENGTH(), NOT NULL, JSON(), REGEX(). A user is also able to define their own constraints if they implement it and put them on Cassandra’s class path.

A simple example of an in-line constraint:

CREATE TABLE users (

username text PRIMARY KEY,

age int CHECK age >= 0 and age < 120

);

Constraints are not supported for UDTs (User-Defined Types) nor collections (except for using NOT NULL for frozen collections).

Enabling constraints closer to the data is a subtle but mighty way for operators to ensure that data goes into the database correctly. By defining rules just once, application code is simplified, more robust, and prevents validation from being bypassed. Those who have worked with MySQL, Postgres, or MongoDB will enjoy this addition to Cassandra.

CEP-51: Support “Include” Semantics for cassandra.yaml

The cassandra.yaml file holds important settings for storage, memory, replication, compaction, and more. It’s no surprise that the average size of the file around 1,000 lines (though, yes—most are comments). CEP-51 enables splitting the cassandra.yaml configuration into multiple files using includes semantics. From the outside, this feels like a small change, but the implications are huge if a user chooses to opt-in.

In general, the size of the configuration file makes it difficult to manage and coordinate changes. It’s often the case that multiple teams manage various aspects of the single file. In addition, cassandra.yaml permissions are readable for those with access to this file, meaning private information like credentials are comingled with all other settings. There is risk from an operational and security standpoint.

Enabling the new semantics and therefore modularity for the configuration file eases management, deployment, complexity around environment-specific settings, and security in one shot. The configuration file follows the principle of least privilege once the cassandra.yaml is broken up into smaller, well-defined files; sensitive configuration settings are separated out from general settings with fine-grained access for the individual files. With the feature enabled, different development teams are better equipped to deploy safely and independently.

If you’ve deployed your Cassandra cluster on the NetApp Instaclustr platform, the cassandra.yaml file is already configured and managed for you. We pride ourselves on making it easy for you to get up and running fast.

CEP-52: Schema annotations for Apache Cassandra

With extensive review by the NetApp Instaclustr team and Stefan Miklosovic, CEP-52 introduces schema annotations in CQL allowing in-line comments and labels of schema elements such as keyspaces, tables, columns, and User Defined Types (UDT). Users can easily define and alter comments and labels on these elements. They can be copied over when desired using CREATE TABLE LIKE syntax. Comments are stored as plain text while labels are stored as structured metadata.

Comments and labels serve different annotation purposes: Comments document what a schema object is for, whereas labels describe how sensitive or controlled it is meant to be. For example, labels can be used to identify columns as “PII” or “confidential”, while the comment on that column explains usage, e.g. “Last login timestamp.”

Users can query these annotations. CEP-52 defines two new read-only tables (system_views.schema_comments and system_views.schema_security_labels) to store comments and security labels so objects with comments can be returned as a list or a user/machine process can query for specific labels, beneficial for auditing and classification. Note that adding security labels are descriptive metadata and do not enforce access control to the data.

CEP-53: Cassandra rolling restarts via Sidecar

Sidecar is an auxiliary component in the Cassandra ecosystem that exposes cluster management and streaming capabilities through APIs. Introducing rolling restarts through Sidecar, this feature is designed to provide operators with more efficient and safer restarts without cluster-wide downtime. More specifically, operators can monitor, pause, resume, and abort restarts all through an API with configurable options if restarts fail.

Rolling restarts brings operators a step closer to cluster-wide operations and lifecycle management via Sidecar. Operators will be able to configure the number of nodes to restart concurrently with minimal risk as this CEP unleashes clear states as a node progresses through a restart. Accounting for a variety of edge cases, an operator can feel assured that, for example, a non-functioning sidecar won’t derail operations.

The current process for restarting a node is a multi-step, manual process, which does not scale for large cluster sizes (and is also tedious for small clusters). Restarting clusters previously lacked a streamlined approach as each node needed to be restarted one at a time, making the process time-intensive and error-prone.

Though Sidecar is still considered WIP, it’s got big plans to improve operating large clusters!

The NetApp Instaclustr Platform, in conjunction with our expert TechOps team already orchestrates these laborious tasks for our Cassandra customers with a high level of care to ensure their cluster stays online. Restarting or upgrading your Cassandra nodes is a huge pain-point for operators, but it doesn’t have to be when using our managed platform (with round-the-clock support!)

CEP-54: Zstd with dictionary SSTable compression

CEP-54, with NetApp Instaclustr’s collaboration, aims to add support Zstd with dictionary compression for SSTables. Zstd, or Zstandard, is a fast, lossless data compression algorithm that boasts impressive ratio and speed and has been supported in Cassandra since 4.0. Certain workloads can benefit from significantly faster read/write performance, reduced storage footprint, and increased storage device lifetime when using dictionary compression.

At a high level, operators choose a table they want to compress with a dictionary. A dictionary must be trained first on a small amount of already present data (recommended no more than 10MiB). The result of a training is a dictionary, which is stored cluster-wide for all other nodes to use, and this dictionary is used for all subsequent writes of SSTables to a disk.

Workloads with structured data of similar rows benefit most from Zstd with dictionary compression. Some examples of ideal workloads include event logs, telemetry data, metadata tables with templated messages. Think: repeated row data. If the table data is too unstructured or random, this feature likely won’t be optimal for dictionary compression, however plain Zstd will still be an excellent option.

New SSTables with dictionaries are readable across nodes and can stream, repair, and backup. Existing tables are unaffected if dictionary compression is not enabled. Too many unique dictionaries hurt decompression; use minimal dictionaries (recommended dictionary size is about 100KiB and one dictionary per table) and only adopt new ones when they’re noticeably better.

CEP-55: Generated role names

 CEP-55 adds support to create users/roles without supplying a name, simplifying

user management, especially when generating users and roles in bulk. With an example syntax, CREATE GENERATED ROLE WITH GENERATED PASSWORD, new keys are placed in a newly introduced configuration section in cassandra.yaml under “role_name_policy.”

Stefan Miklosovic, our Cassandra engineer at NetApp Instaclustr, created this CEP as a logical follow up to CEP-24 (password validation/generation), which he authored as well. These quality-of-life improvements let operators spend less time doing trivial tasks with high-risk potential and more time on truly complex matters.

Manual name selection seems trivial until a hundred role names need to be generated; now there is a security risk if the new usernames—or worse passwords—are easily guessable. With CEP-55, the generated role name will be UUID-like, with optional prefix/suffix and size hints, however a pluggable policy is available to generate and validate names as well. This is an opt-in feature with no effect to the existing method of generating role names.

The future of Apache Cassandra is bright

 These Cassandra Enhancement Proposals demonstrate a strong commitment to making Apache Cassandra more powerful, secure, and easier to operate. By staying on top of these updates, we ensure our managed platform seamlessly supports future releases that accelerate your business needs.

At NetApp Instaclustr, our expert TechOps team already orchestrates laborious tasks like restarts and upgrades for our Apache Cassandra customers, ensuring their clusters stay online. Our platform handles the complexity so you can get up and running fast.

Learn more about our fully managed and hosted Apache Cassandra offering and try it for free today!

The post Stay ahead with Apache Cassandra®: 2025 CEP highlights appeared first on Instaclustr.

Vector search benchmarking: Embeddings, insertion, and searching documents with ClickHouse® and Apache Cassandra®

4 November 2025, 12:05 pm by Apache Cassandra - Instaclustr

Welcome back to our series on vector search benchmarking. In part 1, we dove into setting up a benchmarking project and explored how to implement vector search in PostgreSQL from the example code in GitHub. We saw how a hands-on project with students from Northeastern University provided a real-world testing ground for Retrieval-Augmented Generation (RAG) pipelines.

Now, we’re continuing our journey by exploring two more powerful open source technologies: ClickHouse and Apache Cassandra. Both handle vector data differently and understanding their methods is key to effective vector search benchmarking. Using the same student project as our guide, this post will examine the code for embedding, inserting, and retrieving data to see how these technologies stack up.

Let’s get started.

Vector search benchmarking with ClickHouse

ClickHouse is a column-oriented database management system known for its incredible speed in analytical queries. It’s no surprise that it has also embraced vector search. Let’s see how the student project team implemented and benchmarked the core components.

Step 1: Embedding and inserting data

scripts/vectorize_and_upload.py

This is the file that handles Step 1 of the pipeline for ClickHouse. Embeddings in this file (scripts/vectorize_and_upload.py) are used as vector representations of Guardian news articles for the purpose of storing them in a database and performing semantic search. Here’s how embeddings are handled step-by-step (the steps look similar to PostgreSQL).

First up, is the generation of embeddings. The same SentenceTransformer model used in part 1 (all-MiniLM-L6-v2) is loaded in the class constructor. In the method generate_embeddings(self, articles), for each article:

  • The article’s title and body are concatenated into a text string.
  • The model generates an embedding vector (self.model.encode(text_for_embedding)), which is a numerical representation of the article’s semantic content.
  • The embedding is added to the article’s dictionary under the key embedding.

Then the embeddings are stored in ClickHouse as follows.

  • The database table guardian_articles is created with an embedding Array(Float64) NOT NULL column specifically to store these vectors.
  • In upload_to_clickhouse_debug(self, articles_with_embeddings), the script inserts articles into ClickHouse, including the embedding vector as part of each row.
Step 2: Vector search and retrieval

services/clickhouse/clickhouse_dao.py

The steps to search are the same as for PostgreSQL in part 1. Here’s part of the related_articles method for ClickHouse:

def related_articles(self, query: str, limit: int = 5):

"""Search for similar articles using vector similarity""" ... query_embedding = self.model.encode(query).tolist() search_query = f""" SELECT url, title, body, publication_date, cosineDistance(embedding, {query_embedding}) as distance FROM guardian_articles ORDER BY distance ASC LIMIT {limit} """ ...

When searching for related articles, it encodes the query into an embedding, then performs a vector similarity search in ClickHouse using cosineDistance between stored embeddings and the query embedding, and results are ordered by similarity, returning the most relevant articles.

Vector search benchmarking with Apache Cassandra

Next, let’s turn our attention to Apache Cassandra. As a distributed NoSQL database, Cassandra is designed for high availability and scalability, making it an intriguing option for large-scale RAG applications.

Step 1: Embedding and inserting data

scripts/pull_docs_cassandra.py

As in the above examples, embeddings in this file are used to convert article text (body) into numerical vector representations for storage and later retrieval in Cassandra.

For each article, the code extracts the body and computes the embeddings:

embedding = model.encode(body) embedding_list = [float(x) for x in embedding]
  • model.encode(body) converts the text to a NumPy array of 384 floats.
  • The array is converted to a standard Python list of floats for Cassandra storage.

Next, the embedding is stored in the vector column of the articles table using a CQL INSERT:

insert_cql = SimpleStatement(""" INSERT INTO articles (url, title, body, publication_date, vector) VALUES (%s, %s, %s, %s, %s) IF NOT EXISTS; """) result = session.execute(insert_cql, (url, title, body, publication_date, embedding_list))

The schema for the table specifies: vector vector<float, 384>, meaning each article has a corresponding 384-dimensional embedding. The code also creates a custom index for the vector column:

session.execute(""" CREATE CUSTOM INDEX IF NOT EXISTS ann_index ON articles(vector) USING 'StorageAttachedIndex'; """)

This enables efficient vector (ANN: Approximate Nearest Neighbor) search capabilities, allowing similarity queries on stored embeddings.

A key part of the setup is the schema and indexing. The Cassandra schema in services/cassandra/init/01-schema.cql defines the vector column.

Being a NoSQL database, Cassandra schemas are a bit different to normal SQL databases, so it’s worth taking a closer look. This Cassandra schema is designed to support Retrieval-Augmented Generation (RAG) architectures, which combine information retrieval with generative models to answer queries using both stored data and generative AI. Here’s how the schema supports RAG:

  • Keyspace and table structure
    • Keyspace (vectorembeds): Analogous to a database, this isolates all RAG-related tables and data.
    • Table (articles): Stores retrievable knowledge sources (e.g., articles) for use in generation.
  • Table columns
    • url TEXT PRIMARY KEY: Uniquely identifies each article/document, useful for referencing and deduplication.
    • title TEXT and body TEXT: Store the actual content and metadata, which may be retrieved and passed to the generative model during RAG.
    • publication_date TIMESTAMP: Enables filtering or ranking based on recency.
    • vector VECTOR<FLOAT, 384>: Stores the embedding representation of the article. The new Cassandra vector data type is documented here.
  • Indexing
    • Sets up an Approximate Nearest Neighbor (ANN) index using Cassandra’s Storage Attached Index.

More information about Cassandra vector support is in the documentation.

Step 2: Vector search and retrieval

The retrieval logic in services/cassandra/cassandra_dao.py showcases the elegance of Cassandra’s vector search capabilities.

The code to create the query embeddings and perform the query is similar to the previous examples, but the CQL query to retrieve similar documents looks like this:

query_cql = """ SELECT url, title, body, publication_date FROM articles ORDER BY vector ANN OF ? LIMIT ? """ prepared = self.client.prepare(query_cql) rows = self.client.execute(prepared, (emb, limit))
What have we learned?

By exploring the code from this RAG benchmarking project we’ve seen distinct approaches to vector search. Here’s a summary of key takeaways:

  • Critical steps in the process:
    • Step 1: Embedding articles and inserting them into the vector databases.
    • Step 2: Embedding queries and retrieving relevant articles from the database.
  • Key design pattern:
    • The DAO (Data Access Object) design pattern provides a clean, scalable way to support multiple databases.
    • This approach could extend to other databases, such as OpenSearch, in the future.
  • Additional insights:
    • It’s possible to perform vector searches over the latest documents, pre-empting queries, and potentially speeding up the pipeline.
What’s next?

So far, we have only scratched the surface. The students built a complete benchmarking application with a GUI (using Steamlit), used multiple other interesting components (e.g. LangChain, LangGraph, FastAPI and uvicorn), Grafana and LangSmith for metrics, and Claude to use the retrieved articles to answer questions, and Docker support for the components. They also revealed some preliminary performance results! Here’s what the final system looked like (this and the previous blog focused on the bottom boxes only).

student-built benchmarking application flow chart

In a future article, we will examine the rest of the application code, look at the preliminary performance results the students uncovered, and discuss what they tell us about the trade-offs between these different databases.

Ready to learn more right now? We have a wealth of resources on vector search. You can explore our blogs on ClickHouse vector search and Apache Cassandra Vector Search (here, here, and here) to deepen your understanding.

The post Vector search benchmarking: Embeddings, insertion, and searching documents with ClickHouse® and Apache Cassandra® appeared first on Instaclustr.

Optimizing Cassandra Repair for Higher Node Density

22 October 2025, 12:00 am by Posts on RustyRazorblade Consulting

This is the fourth post in my series on improving the cost efficiency of Apache Cassandra through increased node density. In the last post, we explored compaction strategies, specifically the new UnifiedCompactionStrategy (UCS) which appeared in Cassandra 5.

Now, we’ll tackle another aspect of Cassandra operations that directly impacts how much data you can efficiently store per node: repair. Having worked with repairs across hundreds of clusters since 2012, I’ve developed strong opinions on what works and what doesn’t when you’re pushing the limits of node density.

Building easy-cass-mcp: An MCP Server for Cassandra Operations

26 August 2025, 12:00 am by Posts on RustyRazorblade Consulting

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.

easy-cass-stress Joins the Apache Cassandra Project

19 August 2025, 12:00 am by Posts on RustyRazorblade Consulting

I’m taking a quick break from my series on Cassandra node density to share some news with the Cassandra community: easy-cass-stress has officially been donated to the Apache Software Foundation and is now part of the Apache Cassandra project ecosystem as cassandra-easy-stress.

Why This Matters

Over the past decade, I’ve worked with countless teams struggling with Cassandra performance testing and benchmarking. The reality is that stress testing distributed systems requires tools that can accurately simulate real-world workloads. Many tools make this difficult by requiring the end user to learn complex configurations and nuance. While consulting at The Last Pickle, I set out to create an easy to use tool that lets people get up and running in just a few minutes

Azure fault domains vs availability zones: Achieving zero downtime migrations

6 August 2025, 12:00 pm by Apache Cassandra - Instaclustr

The challenges of operating production-ready enterprise systems in the cloud are ensuring applications remain up to date, secure and benefit from the latest features. This can include operating system or application version upgrades, but it is not limited to advancements in cloud provider offerings or the retirement of older ones. Recently, NetApp Instaclustr undertook a migration activity for (almost) all our Azure fault domain customers to availability zones and Basic SKU IP addresses.

Understanding Azure fault domains vs availability zones

“Azure fault domain vs availability zone” reflects a critical distinction in ensuring high availability and fault tolerance. Fault domains offer physical separation within a data center, while availability zones expand on this by distributing workloads across data centers within a region. This enhances resiliency against failures, making availability zones a clear step forward.

The need for migrating from fault domains to availability zones

NetApp Instaclustr has supported Azure as a cloud provider for our Managed open source offerings since 2016. Originally this offering was distributed across fault domains to ensure high availability using “Basic SKU public IP Addresses”, but this solution had some drawbacks when performing particular types of maintenance. Once released by Azure in several regions we extended our Azure support to availability zones which have a number of benefits including more explicit placement of additional resources, and we leveraged “Standard SKU Public IP’s” as part of this deployment.

When we introduced availability zones, we encouraged customers to provision new workloads in them. We also supported migrating workloads to availability zones, but we had not pushed existing deployments to do the migration. This was initially due to the reduced number of regions that supported availability zones.

In early 2024, we were notified that Azure would be retiring support for Basic SKU public IP addresses in September 2025. Notably, no new Basic SKU public IPs would be created after March 1, 2025. For us and our customers, this had the potential to impact cluster availability and stability – as we would be unable to add nodes, and some replacement operations would fail.

Very quickly we identified that we needed to migrate all customer deployments from Basic SKU to Standard SKU public IPs. Unfortunately, this operation involves node-level downtime as we needed to stop each individual virtual machine, detach the IP address, upgrade the IP address to the new SKU, and then reattach and start the instance. For customers who are operating their applications in line with our recommendations, node-level downtime does not have an impact on overall application availability, however it can increase strain on the remaining nodes.

Given that we needed to perform this potentially disruptive maintenance by a specific date, we decided to evaluate the migration of existing customers to Azure availability zones.

Key migration consideration for Cassandra clusters

As with any migration, we were looking at performing this with zero application downtime, minimal additional infrastructure costs, and as safe as possible. For some customers, we also needed to ensure that we do not change the contact IP addresses of the deployment, as this may require application updates from their side. We quickly worked out several ways to achieve this migration, each with its own set of pros and cons.

For our Cassandra customers, our go to method for changing cluster topology is through a data center migration. This is our zero-downtime migration method that we have completed hundreds of times, and have vast experience in executing. The benefit here is that we can be extremely confident of application uptime through the entire operation and be confident in the ability to pause and reverse the migration if issues are encountered. The major drawback to a data center migration is the increased infrastructure cost during the migration period – as you effectively need to have both your source and destination data centers running simultaneously throughout the operation. The other item of note, is that you will need to update your cluster contact points to the new data center.

For clusters running other applications, or customers who are more cost conscious, we evaluated doing a “node by node” migration from Basic SKU IP addresses in fault domains, to Standard SKU IP addresses in availability zones. This does not have any short-term increased infrastructure cost, however the upgrade from Basic SKU public IP to Standard SKU is irreversible, and different types of public IPs cannot coexist within the same fault domain. Additionally, this method comes with reduced rollback abilities. Therefore, we needed to devise a plan to minimize risks for our customers and ensure a seamless migration.

Developing a zero-downtime node-by-node migration strategy

To achieve a zero-downtime “node by node” migration, we explored several options, one of which involved building tooling to migrate the instances in the cloud provider but preserve all existing configurations. The tooling automates the migration process as follows:

  1. Begin with stopping the first VM in the cluster. For cluster availability, ensure that only 1 VM is stopped at any time.
  2. Create an OS disk snapshot and verify its success, then do the same for data disks
  3. Ensure all snapshots are created and generate new disks from snapshots
  4. Create a new network interface card (NIC) and confirm its status is green
  5. Create a new VM and attach the disks, confirming that the new VM is up and running
  6. Update the private IP address and verify the change
  7. The public IP SKU will then be upgraded, making sure this operation is successful
  8. The public IP will then be reattached to the VM
  9. Start the VM

Even though the disks are created from snapshots of the original disks, we encountered several discrepancies in our testing, with settings between the original VM and the new VM. For instance, certain configurations, such as caching policies, did not automatically carry over, requiring manual adjustments to align with our managed standards.

Recognizing these challenges, we decided to extend our existing node replacement mechanism to streamline our migration process. This is done so that a new instance is provisioned with a new OS disk with the same IP and application data. The new node is configured by the Instaclustr Managed Platform to be the same as the original node.

The next challenge: our existing solution is built so that the replaced node was provisioned to be the exact same as the original. However, for this operation we needed the new node to be placed in an availability zone instead of the same fault domain. This required us to extend the replacement operation so that when we triggered the replacement, the new node was placed in the desired availability zone. Once this operation completed, we had a replacement tool that ensured that the new instance was correctly provisioned in the availability zone, with a Standard SKU, and without data loss.

Now that we had two very viable options, we went back to our existing Azure customers to outline the problem space, and the operations that needed to be completed. We worked with all impacted customers on the best migration path for their specific use case or application and worked out the best time to complete the migration. Where possible, we first performed the migration on any test or QA environments before moving onto production environments.

Collaborative customer migration success

Some of our Cassandra customers opted to perform the migration using our data center migration path, however most customers opted for the node-by-node method. We successfully migrated the existing Azure fault domain clusters over to the Availability Zone that we were targeting, with only a very small number of clusters remaining. These clusters are operating in Azure regions which do not yet support availability zones, but we were able to successfully upgrade their public IP from Basic SKUs that are set for retirement to Standard SKUs.

No matter what provider you use, the pace of development in cloud computing can require significant effort to support ongoing maintenance and feature adoption to take advantage of new opportunities. For business-critical applications, being able to migrate to new infrastructure and leverage these opportunities while understanding the limitations and impact they have on other services is essential.

NetApp Instaclustr has a depth of experience in supporting business critical applications in the cloud. You can read more about another large-scale migration we completed The worlds Largest Apache Kafka and Apache Cassandra Migration or head over to our console for a free trial of the Instaclustr Managed Platform.

The post Azure fault domains vs availability zones: Achieving zero downtime migrations appeared first on Instaclustr.

Compaction Strategies, Performance, and Their Impact on Cassandra Node Density

10 July 2025, 12:00 am by Posts on RustyRazorblade Consulting

This is the third post in my series on optimizing Apache Cassandra for maximum cost efficiency through increased node density. In the first post, I examined how streaming operations impact node density and laid out the groundwork for understanding why higher node density leads to significant cost savings. In the second post, I discussed how compaction throughput is critical to node density and introduced the optimizations we implemented in CASSANDRA-15452 to improve throughput on disaggregated storage like EBS.

Cassandra Compaction Throughput Performance Explained

16 April 2025, 12:00 am by Posts on RustyRazorblade Consulting

This is the second post in my series on improving node density and lowering costs with Apache Cassandra. In the previous post, I examined how streaming performance impacts node density and operational costs. In this post, I’ll focus on compaction throughput, and a recent optimization in Cassandra 5.0.4 that significantly improves it, CASSANDRA-15452.

This post assumes some familiarity with Apache Cassandra storage engine fundamentals. The documentation has a nice section covering the storage engine if you’d like to brush up before reading this post.

How Cassandra Streaming, Performance, Node Density, and Cost are All related

5 March 2025, 12:00 am by Posts on RustyRazorblade Consulting

This is the first post of several I have planned on optimizing Apache Cassandra for maximum cost efficiency. I’ve spent over a decade working with Cassandra and have spent tens of thousands of hours data modeling, fixing issues, writing tools for it, and analyzing it’s performance. I’ve always been fascinated by database performance tuning, even before Cassandra.

A decade ago I filed one of my first issues with the project, where I laid out my target goal of 20TB of data per node. This wasn’t possible for most workloads at the time, but I’ve kept this target in my sights.

Cassandra 5 Released! What's New and How to Try it

9 September 2024, 12:00 am by Posts on RustyRazorblade Consulting

Apache Cassandra 5.0 has officially landed! This highly anticipated release brings a range of new features and performance improvements to one of the most popular NoSQL databases in the world. Having recently hosted a webinar covering the major features of Cassandra 5.0, I’m excited to give a brief overview of the key updates and show you how to easily get hands-on with the latest release using easy-cass-lab.

You can grab the latest release on the Cassandra download page.

easy-cass-lab v5 released

5 August 2024, 12:00 am by Posts on RustyRazorblade Consulting

I’ve got some fun news to start the week off for users of easy-cass-lab: I’ve just released version 5. There are a number of nice improvements and bug fixes in here that should make it more enjoyable, more useful, and lay groundwork for some future enhancements.

  • When the cluster starts, we wait for the storage service to reach NORMAL state, then move to the next node. This is in contrast to the previous behavior where we waited for 2 minutes after starting a node. This queries JMX directly using Swiss Java Knife and is more reliable than the 2-minute method. Please see packer/bin-cassandra/wait-for-up-normal to read through the implementation.
  • Trunk now works correctly. Unfortunately, AxonOps doesn’t support trunk (5.1) yet, and using the agent was causing a startup error. You can test trunk out, but for now the AxonOps integration is disabled.
  • Added a new repl mode. This saves keystrokes and provides some auto-complete functionality and keeps SSH connections open. If you’re going to do a lot of work with ECL this will help you be a little more efficient. You can try this out with ecl repl.
  • Power user feature: Initial support for profiles in AWS regions other than us-west-2. We only provide AMIs for us-west-2, but you can now set up a profile in an alternate region, and build the required AMIs using easy-cass-lab build-image. This feature is still under development and requires using an easy-cass-lab build from source. Credit to Jordan West for contributing this work.
  • Power user feature: Support for multiple profiles. Setting the EASY_CASS_LAB_PROFILE environment variable allows you to configure alternate profiles. This is handy if you want to use multiple regions or have multiple organizations.
  • The project now uses Kotlin instead of Groovy for Gradle configuration.
  • Updated Gradle to 8.9.
  • When using the list command, don’t show the alias “current”.
  • Project cleanup, remove old unused pssh, cassandra build, and async profiler subprojects.

The release has been released to the project’s GitHub page and to homebrew. The project is largely driven by my own consulting needs and for my training. If you’re looking to have some features prioritized please reach out, and we can discuss a consulting engagement.

easy-cass-lab updated with Cassandra 5.0 RC-1 Support

23 July 2024, 12:00 am by Posts on RustyRazorblade Consulting

I’m excited to announce that the latest version of easy-cass-lab now supports Cassandra 5.0 RC-1, which was just made available last week! This update marks a significant milestone, providing users with the ability to test and experiment with the newest Cassandra 5.0 features in a simplified manner. This post will walk you through how to set up a cluster, SSH in, and run your first stress test.

For those new to easy-cass-lab, it’s a tool designed to streamline the setup and management of Cassandra clusters in AWS, making it accessible for both new and experienced users. Whether you’re running tests, developing new features, or just exploring Cassandra, easy-cass-lab is your go-to tool.