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
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 wi
th
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.
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.
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®
-
Apache Kafka and Kafka Connect 4.1.1 are now generally
available.
- Added Client Metrics and Observability feature support for
Kafka in private preview.
- Single CA feature is now available for Apache Kafka clusters.
See
Single CA for more details.
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?
- Explore how to freeze your streaming data for long-term
analytical queries in the future with our two-part blog series:
Freezing streaming data into Apache Iceberg
—Part 1: Using Apache Kafka®Connect Iceberg Sink Connector
introduces Apache Iceberg and demonstrates streaming Kafka data
using the Apache Kafka Connect Iceberg Sink Connector and
Freezing streaming data into Apache Iceberg—Part 2: Using Iceberg Topics examines the experimental
approach of using Kafka Tiered Storage and Iceberg Topics, where
non‑active Kafka segments are copied to remote storage while
remaining transparently readable by Kafka clients.
- Modern search applications go beyond simple keyword matching,
requiring a deep understanding of user intent and context to
deliver relevant, meaningful results.
From keywords to concepts: How OpenSearch® AI search outperforms
traditional search explores how semantic and hybrid search
methods in OpenSearch AI search compare to traditional keyword
search, and how you can use these capabilities for more relevant
results.
- Generative AI and Large Language Models (LLMs) are booming, and
they’ve put a spotlight on a crucial technology: vector search.
Many applications today demand high throughput, low latency, and
constant availability for retrieving information. Slow vector
search can become a significant bottleneck, delaying responses and
degrading the user experience. Our two-part series blogs
Vector search benchmarking: Setting up embeddings, insertion, and
retrieval with PostgreSQL® and
Vector search benchmarking: Embeddings, insertion, and searching
documents with ClickHouse® and Apache Cassandra® explore
hands-on findings from our benchmarking projects, the role of
databases in vector search, how to set up vector search for
embeddings, insertion, and retrieval, and practical strategies for
building faster, more efficient semantic search systems.
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.
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.
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.”
4 March 2026, 1:16 pm by
ScyllaDB
How ShareChat reduced costs for its billion-feature scale
feature store with ScyllaDB “Great system…now please
make it 10 times cheaper.” That’s not exactly what the
ShareChat team wanted to hear after completing a major engineering
feat:
scaling a real-time feature store 1000X without scaling their
database (ScyllaDB). To stretch from supporting 1 million
features per second to supporting 1 billion features per second,
the team already… Redesigned their database schema to store all
features together as protocol buffers and optimized tile
configurations (reduced required rows from 2B to 73M/sec) Switched
their database compaction strategy from incremental to leveled
(doubled database capacity) Forked caching and gRPC libraries to
eliminate mutex contention and connection bottlenecks Applied
object pooling and garbage collector tuning to reduce memory
allocation overhead You can read about those performance
optimizations in
Scaling an ML Feature Store From 1M to 1B Features per Second.
But ShareChat – an Indian leader in a globally competitive social
media market – is always looking to optimize. After reaching this
scalability milestone, the team received a follow-up challenge:
reducing the feature store’s costs by 10X (without compromising
performance, of course).
David Malinge (Sr. Staff
Software Engineer at ShareChat) and
Ivan Burmistrov (then
Principal Software Engineer at ShareChat) shared how they
approached this new challenge in a keynote at Monster Scale Summit
2025. Watch the complete talk, or read the highlights below.
Note: Monster Scale Summit is a free + virtual
conference on extreme scale engineering, with a focus on
data-intensive applications. Learn from luminaries like
antirez, creator of Redis;
Camille
Fournier, author of “The Manager’s Path” and “Platform
Engineering”;
Martin
Kleppmann, author of “Designing Data-Intensive Applications”
and more than 50 others, including engineers from Discord, Disney,
Pinterest, Rivian, LinkedIn, Nextdoor, and American Express.
Register (free) and join us March 11-12 for some lively chats
Background ShareChat is one of the largest Indian media network,
with over 300 million monthly active users. The app’s popularity
stems from its powerful recommendation system – and that’s powered
by their feature store. As Malinge explained, “We process more than
2 billion events daily to compute our features and serve close to a
billion features per second at peak, with P99 latency under 20
milliseconds. We also read more than 30 billion rows per day in
ScyllaDB, so we’re very happy that we’re not charged by the
transaction.” Cloud Cost Optimization: Where Do You Even Start?
When it came time to make this system 10 times cheaper, the team
very quickly realized how complicated and confusing cloud cost
optimization could be. For example, Burmistrov noted:
Cloud
billing is cloudy. AWS and GCP each have around 40,000
different SKUs, which makes it really hard to figure out where your
money’s actually going. And cloud providers aren’t exactly
motivated to make this easier for you to understand and debug.
It’s easy to lose track of little things that add
up. Maybe you forgot about an instance that’s still
running. Maybe there’s an old deployment nobody uses anymore. Or
perhaps you have storage buckets filled with data that should have
expired by now (e.g., via Time to Live [TTL]). It all accumulates
over time.
Your cost intuition from on-prem doesn’t
necessarily translate to the cloud. Something that was
cost-efficient in your own data center might be expensive in the
cloud, and what works well on one cloud provider might not be
cost-effective on another. For the first optimization step, the
team became sticklers for “hygiene”: clearing out anything they
didn’t really need. This involved a deep cleaning for forgotten
instances and deployments, unused buckets, data without proper
TTLs, and overprovisioning. Having proper attribution was critical
here. As Burmistrov explained, “Every workload, every instance, and
every resource must be attributed to a specific service and a
specific team. Without attribution, cost optimization is a global
problem. With attribution, it becomes a local problem. Once each
team can clearly see the costs associated with their own services,
optimization becomes much easier. The team that owns the service
has both the context and the incentive to improve its cost profile.
They can see which components are expensive and decide what to do
about them.” Cloud Trap 1: Getting Sucked Into Unsustainable Costs
Next, they shifted focus to challenges unique to running
applications in the cloud. To get the required cost savings, they
had to navigate around a few cloud traps. The first trap was the
allure and ease of using the cloud provider’s own products –
particularly, databases. “They’re great to start with, but at scale
they become painful in terms of cost,” explained Burmistrov.
Scaling can be particularly costly for solutions that use a metered
pricing model (e.g., based on traffic). “We used several GCP
databases, including Bigtable and Spanner, but they became
expensive and, more importantly, those costs were largely out of
our control, we had little leverage over cost,” continued
Burmistrov. “So we migrated many workloads to ScyllaDB. Today, more
than 30 ScyllaDB clusters are deployed across the organization,
including for our feature store use case. Besides stability and low
latency, ScyllaDB gives us strong cost control. We can choose
instance types, merge use cases into a single cluster, and run at
high utilization. ScyllaDB works well at 80%, 90%, even close to
100% utilization, which gives us a very strong cost profile.” Cloud
Trap 2: Kubernetes Wastage Next, the team tackled Kubernetes
wastage. In Kubernetes, you deploy containers into pods, but you
pay for nodes, which are actual VMs. You typically choose node
types upfront – for example, nodes with 4 CPUs and 16 GB of memory.
However, over time, workloads change, teams change, and these nodes
are no longer optimal. Pods cannot fully occupy the nodes, either
because of CPU, memory, or scheduling constraints. At that point,
you’re paying for resources that aren’t being used. “You may
decide, ‘Okay, let’s isolate workloads into separate node pools,’”
explained Burmistrov. “But it’s not a solution because, as shown in
the image below, we have one node completely wasted.” Simple
isolation just moves waste around. The solution: dynamic node
allocation based on workloads. Options include open source
solutions like Karpenter, cloud-specific ones like GKE Autopilot,
or commercial multi-cloud solutions like Cast AI. ShareChat likes
Cast AI because it lets them fine-tune the configuration with
respect to long-term commitments, spot instances, and other pricing
impacts. Cloud Trap 3: Network Costs (“The Cloud Tax”) And then
there’s network costs, which the ShareChat team calls “the cloud
tax.” Massive apps like ShareChat deploy across multiple zones for
high availability. However, multiple zones need to communicate with
one another, and the traffic between zones comes with its own cost:
Network Inter-Zone Egress (NIZE). That’s the outbound network
traffic between availability zones within the same region. It’s
billed separately by many cloud providers For example, if you
deploy ScyllaDB in three GCP zones with two nodes per zone and use
a non-ScyllaDB driver (not recommended), reads may cross zones both
at the client level and inside the cluster. For traffic of volume
T, you pay for T in NIZE. ScyllaDB drivers help here. As Burmistrov
explained, “ Using ScyllaDB’s token-aware routing removes the extra
hop inside the cluster, reducing inter-zone traffic. Using
token-aware plus zone-aware routing ensures reads stay within the
same zone, reducing inter-zone traffic to zero for reads.” Removing
the extra hop cuts NIZE down to about 2/3 of T. On the write path,
it’s a little different because replication is required. Burmistrov
continued, “With three zones, writes generate 2 times T of
inter-zone traffic. You can trade availability for cost by using
two zones instead of three, reducing this to 1.5 times T. ScyllaDB
also lets teams model each zone as a separate data center. In that
case, for traffic T, you pay for T of inter-zone traffic. You
generally can’t go lower unless you deploy in a single zone.” Tip:
Oracle Cloud and Azure don’t charge for inter-zone traffic. If you
use one of these cloud providers, you can deploy across three zones
with zero inter-zone cost. Database Layer Optimization Another
challenge: ShareChat’s generally stable read latencies would spike
beyond their SLAs when write-heavy workloads would occur (like a
backfill job, for example). The usual option – just scale up the
database – would be simple, but the team wanted to reduce costs.
Isolating reads and writes into separate data centers could
technically improve performance, but that would be even worse from
the cost perspective. That approach would double the infrastructure
and probably lead to underutilization. Ultimately, they discovered
and applied ScyllaDB’s workload prioritization. This lets them
control how their various workloads compete for system resources.
Malinge explained, “Under the hood, this relies on ScyllaDB’s
thread-per-core architecture. Each core runs an async scheduler
with multiple queues, each with its own priority. Workload
prioritization maps directly to these priorities. Looking at the
image, we have a very high share of compute for serving because we
have strong SLAs on the read path, which is user facing. Most of
the rest goes to less latency-sensitive workloads from asynchronous
jobs, like writing the features to the database. We also keep a
tiny share for manual queries (debugging, for example). This
enables us to have exactly what we want – different latencies for
reads and writes – and that allowed us to have the best possible
serving for our features.” Feature Serving Layer Optimization That
serving layer is a distributed gRPC (Google Remote Procedure Call)
service responsible for caching and handling consumer requests. The
team made some cost optimizations here too. One of the most
impactful was a clever shortcut: instead of fully deserializing
complex Protobuf messages, they treated repeated messages as
serialized byte blobs. Since Protobuf encodes embedded messages
using the same wire format as bytes, they could simply append these
serialized records to merge data. With that, they could skip the
heavy lift of fully unpacking and rebuilding the messages from
scratch. That optimization alone could be the subject of an entire
article; please see the video (starting at 18:15) for a detailed
walkthrough of their approach. Malinge’s top lesson learned from
optimizing this layer: “The first advice is the Captain Obvious
one: don’t go blindly. We set up continuous profiling very early
on. Nowadays, there are tons of tools available. Integration is
super straightforward. You might recognize the vanilla GCP profiler
in the image below. It’s just four lines of code to add in Go
programs, and this has really helped us on our quest to reduce
costs. We’ve actually unlocked more than a 50% reduction in compute
by doing optimizations guided by continuous profiling.” Another
lesson learned: if you’re using protobuf at high-RPS, serde is
probably burning your CPU. Even with ~95% cache hit rates, the hot
path was still deserializing protos, merging them, and serializing
them again just to stitch responses together. Most of that work was
pointless. The team ended up leveraging protobuf’s wire format,
where repeated fields are just sequences of records and embedded
messages can be treated as raw bytes (no deserialization). They
switched to this “lazy” deserialization and merged cached protos
without ever touching individual fields. For a practical example,
see this repository
david-sharechat/lazy-proto.
And one parting tip: the wins compound fast. Benchmarking showed
lazy merging was about 6 times faster, with about a third of the
allocations. In production, that meant lower compute bills and
better tail latency. Cost Optimization Actually Fostered Innovation
The team’s smart work here underscores that cost optimizations
don’t have to compromise the product. They can actually act as a
catalyst for better system design. Malinge left us with this: “Our
cost savings initiatives actually led to a lot of innovations. As I
tried to represent in the left quadrant, there is a very unhealthy
way to look at cost savings – one that focuses on shortcuts that
negatively impact your product. The key is to stay on the right
side of this quadrant, to aim for the sweet spot of reducing costs
while improving the product.”
3 March 2026, 1:32 pm by
ScyllaDB
Lessons learned on data modeling, cache optimization, and
hardware selection Agoda is the Singapore wing of
Booking Holdings, the
world’s leading provider of online travel (the brand behind
Booking.com, Kayak, Priceline, etc.). From January 2023 to February
2025, Agoda server traffic spiked by 50 times. That’s fantastic
business growth, but also the trigger for an interesting
engineering challenge. Specifically, the team had to determine how
to scale their ScyllaDB-backed online feature store to maintain
10ms P99 latencies despite this growth. Complicating the situation,
traffic was highly bursty, cache hit rates were unpredictable and
cold-cache scenarios could flood the database with duplicate read
requests in a matter of seconds. At Monster Scale Summit 2025,
Worakarn Isaratham, lead software engineer at Agoda,shared how they
tackled the challenge. You can watch his entire talk or read the
highlights below.
Note: Monster Scale Summit is a
free + virtual conference on extreme scale engineering, with a
focus on data-intensive applications. Learn from luminaries like
antirez, creator of Redis;
Camille
Fournier, author of “The Manager’s Path” and “Platform
Engineering”;
Martin
Kleppmann, author of “Designing Data-Intensive Applications”
and more than 50 others, including engineers from Discord, Disney,
Pinterest, Rivian, LinkedIn, Nextdoor, and American Express.
Register (free) and join us March 11-12 for some lively chats.
Background: A feature store powered by ScyllaDB and DragonflyDB
Agoda operates an in-house feature store that supports both offline
model training and online inference. For anyone not familiar with
feature stores, Isaratham provided a quick primer. A feature store
is a centralized repository designed for managing and serving
machine learning features. In the context of machine learning, a
feature is a measurable property or characteristic of a data point
used as input to models. The feature store helps manage features
across the entire machine learning pipeline — from data ingestion
to model training to inference. Feature stores are integral to
Agoda’s business. Isaratham explained: “We’re a digital travel
platform and some use cases are directly tied to our product. For
example, we try to predict what users want to see, which hotels to
recommend and what promotions to serve. On the more technical side,
we use it for things like bot detection. The model uses traffic
patterns to predict whether a user is a bot, and if so, we can
block or deprioritize requests. So the feature store is essential
for both product and engineering at Agoda. We’ve got tools to help
create feature ingestion pipelines, model training, and the focus
here: online feature serving.” One layer deeper into how it works:
“We’re currently serving about 3.5 million entities per second
(EPS) to our users. About half the features are served from cache
within the client SDK, which we provide in Scala and Python. That
means 1.7 million entities per second reach our application
servers. These are written in Rust, running in our internal
Kubernetes pods in our private cloud. From the app servers, we
first check if features exist in the cache. We use DragonflyDB as a
non-persistent centralized cache. If it’s not in the cache, then we
go to ScyllaDB, our source of truth.” ScyllaDB is a
high-performance database for workloads that require ultra-low
latency at scale. Agoda’s current ScyllaDB cluster is deployed as
six bare-metal nodes, replicated across four data centers. Under
steady-state conditions, ScyllaDB serves about 200K entities per
second across all data centers while meeting a service-level
agreement (SLA) of 10ms P99 latency. (In practice, their latencies
are typically even lower than their SLA requires.) Traffic growth
and bursty workloads However, it wasn’t always that smooth and
steady. Around mid-2023, they hit a major capacity problem when a
new user wanted to onboard to the Agoda feature store. Their
traffic pattern was super bursty: It was normally low, but
occasionally flooded them with requests triggered by external
signals. These were cold-cache scenarios, where the cache couldn’t
help. Isaratham shared, “Bursts reached 120K EPS, which was 12
times the normal load back then.” Request duplication exacerbated
the situation. Many identical requests arrived in quick succession.
Instead of one request populating the cache and subsequent requests
benefiting, all of them hit ScyllaDB at the same time — a classic
cache stampede. They also retried failed requests until they
succeeded – and that kept the pressure high. This load involved two
data centers. One slowed down but remained online. The other was
effectively taken out of service. More details from Worakarn: “On
the bad DC, error rates were high and retries took 40 minutes to
clear; on the good one, it only took a few minutes. Metrics showed
that ScyllaDB read latency spiked into seconds instead of
milliseconds.” Diagnosing the bottleneck So, they compared setups
and found the difference: the problematic data center used SATA
SSDs while the better one used NVMe SSDs. SATA (serial advanced
technology attachment) was already old tech, even then. The team’s
speed tests suggested that replacing the disks would yield a 10X
read performance boost – and better write rates too. The team
ordered new disks immediately. However, given that the disks
wouldn’t arrive for months, they had to figure out a survival
strategy until then. As Isaratham shared, “Capacity tests and
projections showed that we would hit limits within eight or nine
months even without new load – and sooner with it. So, we worked
with users to add more aggressive client-side caching, remove
unnecessary requests and smooth out bursts. That reduced the new
load from 120K to 7K EPS. That was enough to keep things stable,
but we were still close to the limit.” Surviving with SATA Given
the imminent capacity cap, the team brainstormed ways to improve
the situation while still on the existing SATA disks. Since you
have to measure before you can improve, getting a clean baseline
was the first order of business. “The earlier capacity numbers were
from real-world traffic, which included caching effects,” Isaratham
detailed. “We wanted to measure cold-cache performance directly.
So, we created artificial load using one-time-use test entities,
bypassed cache in queries and flushed caches before and after each
run. The baseline read capacity on the bad DC was 5K EPS.” With
that baseline set, the team considered a few different approaches.
Data modeling All features from all feature sets were stored in a
single table. The team hoped that splitting tables by feature set
might improve locality and reduce read amplification. It didn’t.
They were already partitioning by feature set and entity, so the
logical reorganization didn’t change the physical layout.
Compaction strategy Given a read-heavy workload with frequent
updates, ScyllaDB documentation recommends the size-tiered
compaction strategy to avoid write amplification. But the team was
most concerned about read latency, so they took a different path.
According to Worakarn: “We tried leveled compaction to reduce the
number of SSTables per read. Tests showed fetching 1KB of data
required reading 70KB from disk, so minimizing SSTable reads was
key. Switching to leveled compaction improved throughput by about
50%.” Larger SSTable summaries ScyllaDB uses summary files to more
efficiently navigate index files. Their size is controlled by the
sstable_summary_ratio setting. Increasing the ratio enlarges the
summary file and that reduces index reads at the cost of additional
memory. The team increased the ratio by 20 times, which boosted
capacity to 20K EPS. This yielded a nice 4X improvement, so they
rolled it out immediately. What a difference a disk makes Finally,
the NVMe disks arrived a few months later. This one change made a
massive difference. Capacity jumped to 300K EPS, a staggering
50–60X improvement. The team rolled out improvements in stages:
first, the summary ratio tweak (for 2–3X breathing room), then the
NVMe upgrade (for 50X capacity). They didn’t apply leveled
compaction in production because it only affects new tables and
would require migration. Anyway, NVMe already solved the problem.
After that, the team shifted focus to other areas: improving
caching, rewriting the application in Rust and adding cache
stampede prevention to reduce the load on ScyllaDB. They still
revisit ScyllaDB occasionally for experiments. A couple of
examples: New partitioning scheme: They tried partitioning by
feature set only and clustering by entity. However, performance was
actually worse, so they didn’t move forward with this idea. Data
remodeling: The application originally stored one row per feature.
Since all features for an entity are always read together, the team
tested storing all features in a single row instead. This improved
performance by 35%, but it requires a table migration. It’s on
their list of things to do later. Lessons learned Isaratham wrapped
it up as follows: “We’d been using ScyllaDB for years without
realizing its full potential, mainly because we hadn’t set it up
correctly. After upgrading disks, benchmarking and tuning data
models, we finally reached proper usage. Getting the basics right –
fast storage, knowing capacity, and matching data models to
workload – made all the difference. That’s how ScyllaDB helped us
achieve 50X scaling.”
