Better “Goodput” Performance through C++ Exception Handling
Some very strange error reporting performance issues we uncovered while working on per-partition query rate limiting — and how we addressed it through C++ exception handling In Retaining Goodput with Query Rate Limiting, I introduced why and how ScyllaDB implemented per-partition rate limiting to maintain stable performance under stress by rejecting excess requests to maintain stable goodput. The implementation works by estimating request rates for each partition and making decisions based on those estimates. And benchmarks confirmed how rate limiting restored goodput, even under stressful conditions, by rejecting problematic requests. However, there was actually an interesting behind-the-scenes twist in that story. After we first coded the solution, we discovered that the performance wasn’t as good as expected. In fact, we were achieving the opposite effect of what we expected. Rejected operations consumed more CPU than the successful ones. This was very strange because tracking per-partition hit counts shouldn’t have been compute-intensive. It turned out that the problem was related to how ScyllaDB reports failures: namely, via C++ exceptions. In this article, I will share more details about the error reporting performance issues that we uncovered while working on per-partition query rate limiting and explain how we addressed them. On C++ (and Seastar) Exceptions Exceptions are notorious in the C++ community. There are many problems with their design, of course. But the most important and relevant one here is the unpredictable and potentially degraded performance that occurs when an exception is actually thrown. Some C++ projects disable exceptions altogether for those reasons. However, it’s hard to avoid exceptions because they’re thrown by the standard library and because they interact with other language features. Seastar, an open-source C++ framework for I/O intensive asynchronous computing, embraces exceptions and provides facilities for handling them correctly. Since ScyllaDB is built on Seastar, the ScyllaDB engineering team is rather accustomed to reporting failures via exceptions. They work fine, provided that errors aren’t very frequent. Under overload, it’s a different story though. We noticed that throwing exceptions in large volumes can introduce a performance bottleneck. This problem affects both existing errors such as timeouts and the new “rate limit exception” that we tried to introduce. This wasn’t the first time that we encountered performance issues with exceptions. In libstdc++, the standard library for GCC, throwing an exception involves acquiring a global mutex. That mutex protects some information important to the runtime that can be modified when a dynamic library is being loaded or unloaded. ScyllaDB doesn’t use dynamic libraries, so we were able to disable the mutex with some clever workarounds. As an unfortunate side effect, we disabled some caching functionality that speeds up further exception throws. However, avoiding scalability bottlenecks was more important to us. Exceptions are usually propagated up the call stack until a try..catch block is encountered. However, in programs with non-standard control flow, it sometimes makes sense to capture the exception and rethrow it elsewhere. For this purpose, std::exception_ptr can be used. Our Seastar framework is a good example of code that uses it. Seastar allows running concurrent, asynchronous tasks that can wait for the results of each other via objects called futures. If a task results in an exception, it is stored in a future as std::exception_ptr and can be later inspected by a different task.future<> do_thing() { return
really_do_thing().finally([] { std::cout << "Did the
thing\n"; }); } future<> really_do_thing() { if (fail_flag) {
return make_exception_future<>( std::runtime_error("oh
no!")); } else { return make_ready_future<>(); } }
Seastar nicely reduces the time spent in the exception handling
runtime. In most cases, Seastar is not interested in the exception
itself; it only cares about whether a given future contains an
exception. Because of that, the common control flow primitives such
as then, finally etc. do not have to rethrow and inspect the
exception. They only check whether an exception is present.
Additionally, it’s possible to construct an “exceptional future”
directly, without throwing the exception. Unfortunately, the
standard library doesn’t make it possible to inspect an
std::exception_ptr without rethrowing it. Because each exception
must be inspected and handled appropriately at some point
(sometimes more than once), it’s impossible for us to eliminate
throws if we want to use exceptions and have portable code. We had
to provide a cheaper way to return timeouts and “rate limit
exceptions.” We tried two approaches. Approach 1: Avoid The
Exceptions The first approach we explored was quite heavy-handed.
It involved plowing through the code and changing all the important
functions to return a boost::result. That’s a type from the boost
library that holds either a successful result or an error. We also
introduced a custom container for holding exceptions that allows
inspecting the exception inside it without having to throw it.
future<result<>> do_thing() { return
really_do_thing().then( [] (result<> res) ->
result<> { if (res) { // handle success } else { // handle
failure } } ); } This approach worked, but had numerous
drawbacks. First, it required a lot of work to adapt the existing
code: return types had to be changed, and the boost::result
returned by the functions had to be explicitly checked to see
whether they held an exception or not. Moreover, those checks
introduced a slight overhead on the happy path. We applied this
approach to the coordinator logic. Approach 2: Implement the
Missing Parts Another approach: create our own implementation for
inspecting the value of std::exception_ptr. We encountered
a proposal to extend the std::exception_ptr’s interface that
included adding the possibility to inspect its value without
rethrowing it. The proposal includes an experimental implementation
that uses standard-library specific and ABI-specific constructs to
implement it for some of the major compilers. Inspired by it, we
implemented a small utility function that allows us to match on the
exception’s type and inspect its value, and replaced a bunch of
try..catch blocks with it. std::exception_ptr ep =
get_exception(); if (auto* ex = try_catch(ep)) { // ... } else if
(auto* ex = try_catch(ep)) { // ... } else { // ... } This
is how we eliminated throws in the most important parts of the
replica logic. It was much less work than the previous approach
since we only had to get rid of try-catch blocks and make sure that
exceptions were propagated using the existing, non-throwing
primitives. While the solution is not portable, it works for us
since we use and support only a single toolchain at a time to build
ScyllaDB. However, it can be easy to accidentally reintroduce
performance problems if you’re not careful and forget to use the
non-throwing primitives, including the new try_catch. In contrast,
the first approach does not have this problem. Results: Better
Exception Handling, Better Throughput (and Goodput) To measure the
results of these optimizations on the exception handling path, we
ran a benchmark. We set up a cluster of 3 i3.4xlarge AWS nodes with
ScyllaDB 5.1.0-rc1. We pre-populated it with a small data set that
fits in memory. Then, we ran a write workload to a single
partition. The data included in each request is very small, so the
workload was CPU bound, not I/O bound. Each request had a small
server-side timeout of 10ms.
The benchmarking application gradually increases its write
rate from 50k writes per second to 100k. The chart shows what
happens when ScyllaDB is no longer able to handle the throughput.
There are two runs of the same benchmark, superimposed on the same
charts – a yellow line for ScyllaDB 5.0.3 which handles timeouts in
the old, slow way, and a green line for ScyllaDB 5.1.0-rc1 which
has exception handling improvements. The older version of ScyllaDB
became overwhelmed somewhere around the 60k writes per second mark.
We were pushing the shard to its limit, and some requests
inevitably failed because we set a short timeout. Since processing
timed out requests is more costly than processing a regular
request, the shard very quickly entered a state where all requests
that it processed resulted in timeouts. The new version, which has
better exception handling performance, was able to sustain a larger
throughput. Some timeouts occurred, but they did not overwhelm the
shard completely. Timeouts don’t start to be more prominent until
the 100k requests per second mark. Summary We discovered unexpected
performance issues while implementing a special case of ScyllaDB’s
per-partition query rate limiting. Despite Seastar’s support for
handling exceptions efficiently, throwing exceptions in large
volumes during overload situations became a bottleneck, affecting
both existing errors like timeouts and new exceptions introduced
for rate limiting. We solved the issue by using two different
approaches in different parts of the code: Change the code to pass
information about timeouts by returning boost::result instead of
throwing exceptions. Implement a utility function that allows
catching exceptions cheaply without throwing them. Benchmarks with
ScyllaDB versions 5.0.3 and 5.1.0-rc1 demonstrated significant
improvements in handling throughput with better exception handling.
While the older version struggled and became overwhelmed around 60k
writes per second, the newer version sustained larger throughput
levels with fewer timeouts, even at 100k requests per second.
Ultimately, these optimizations not only improved exception
handling performance but also contributed to better throughput and
“goodput” under high load scenarios. 
ScyllaDB University Updates, High Availability Lab & NoSQL Training Events
There are many paths to adopting and mastering ScyllaDB, but the vast majority all share a visit to ScyllaDB University. I want to update the ScyllaDB community about recent changes to ScyllaDB University, introduce the High Availability lab, and share some future events and plans. What is ScyllaDB University? For those new to ScyllaDB University, it’s an online learning and training center for ScyllaDB. The material is self-paced and includes theory, quizzes, and hands-on labs that you can run yourself. Access is free; to get started, just create an account. Start Learning ScyllaDB University has six courses and covers most ScyllaDB-related material. As the product evolves, the training material is updated and enhanced. In addition to the self-paced, on-demand material available on ScyllaDB University, we host live training events. These virtual and highly interactive events offer special opportunities for users to learn from the leading ScyllaDB engineers and experts, ask questions, and connect with their peers. The last ScyllaDB University LIVE event took place in March. It had two tracks: an Essentials track covering basic content, as well as an Advanced track covering the latest features and more complex use cases. The next event in the US/EMEA time zones will be on June 18th. Join us at ScyllaDB University LIVE Also, if you’re in India, we’re hosting a special event for you! On May 29, 9:30am-11:30am IST, join us for an interactive workshop where we’ll go hands-on to build and interact with high-performance apps using ScyllaDB. This is a great way to discover the NoSQL strategies used by top teams and apply them in a guided, supportive environment. Register for ScyllaDB Labs India Example Lab: High Availability Here’s a taste of the type of content you will find on ScyllaDB University. The High Availability lab is one of the most popular labs on the platform. It demonstrates what happens when we read and write data while simulating a situation where some of the replica nodes are unavailable, with different consistency levels. ScyllaDB, at its core, is designed to be highly available. With the right settings, it will remain up and available at all times. The database features a peer-to-peer architecture that is leaderless and uses the Gossip protocol for internode communication. This enhances resiliency and scalability. Upon startup and during topology changes such as node addition or removal, nodes automatically discover and communicate with each other, streaming data between them as needed. Multiple copies of the data (replicas) are kept. This is determined by setting a replication factor (RF) to ensure data is stored on multiple nodes, thereby allowing for data redundancy and high availability. Even if a node fails, the data is still available on other nodes, reducing downtime risks. Topology awareness is part of the design. ScyllaDB enhances its fault tolerance through rack and data center awareness, allowing distribution across multiple locations. It supports multi-datacenter replication with customizable replication factors for each site, ensuring data resiliency and availability even in case of significant failures of entire data centers. First, we’ll bring up a 3-node ScyllaDB Docker cluster. Set up a Docker Container with one node, called Node_X:docker run --name Node_X -d
scylladb/scylla:5.2.0 --overprovisioned 1 --smp 1 Create two
more nodes, Node_Y and Node_Z, and add them to the cluster of
Node_X. The command “$(docker inspect –format='{{
.NetworkSettings.IPAddress }}’ Node_X)” translates to the IP
address of Node-X: docker run --name Node_Y -d
scylladb/scylla:5.2.0 --seeds="$(docker inspect --format='{{
.NetworkSettings.IPAddress }}' Node_X)" --overprovisioned 1 --smp
1 docker run --name Node_Z -d
scylladb/scylla:5.2.0 --seeds="$(docker inspect --format='{{
.NetworkSettings.IPAddress }}' Node_X)" --overprovisioned 1 --smp
1 Wait a minute or so and check the node status:
docker exec -it Node_Z nodetool status You’ll
see that eventually, all the nodes have UN for status. U means
up, and N means normal. Read more about Nodetool
Status
Here. Once the nodes are up, and the cluster is set, we
can use the CQL shell to create a table. Run a CQL shell:
docker exec -it Node_Z cqlsh Create a keyspace
called “mykeyspace”, with a Replication Factor of three:
CREATE KEYSPACE mykeyspace WITH REPLICATION = { 'class' :
'NetworkTopologyStrategy', 'replication_factor' : 3};
Next, create a table with three columns: user id, first name, and
last name, and insert some data: use
mykeyspace; CREATE TABLE users ( user_id int,
fname text, lname text, PRIMARY KEY((user_id))); Insert
into the newly created table two rows: insert into
users(user_id, fname, lname) values (1, 'rick', 'sanchez');
insert into users(user_id, fname, lname) values (4, 'rust',
'cohle'); Read the table contents: select *
from users; Now we will see what happens when we
try to read and write data to our table, with varying Consistency
Levels and when some of the nodes are down. Let’s make sure all our
nodes are still up: docker exec -it Node_Z nodetool
status Now, set the Consistency Level to QUORUM and
perform a write: docker exec -it Node_Z cqlsh
use mykeyspace; CONSISTENCY QUORUM
insert into users (user_id, fname, lname) values (7,
'eric', 'cartman'); Read the data to see if the insert
was successful: select * from users; The read
and write operations were successful. What do you think would
happen if we did the same thing with Consistency Level ALL?
CONSISTENCY ALL insert into users
(user_id, fname, lname) values (8, 'lorne', 'malvo');
select * from users; The operations were
successful again. CL=ALL means that we have to read/write to the
number of nodes according to the Replication Factor, 3 in our case.
Since all nodes are up, this works. Next, we’ll take one node down
and check read and write operations with a Consistency Level of
Quorum and ALL. Take down Node_Y and check the status (it might
take some time until the node is actually down): exit
docker stop Node_Y docker exec -it Node_Z
nodetool status Now, set the Consistency Level to QUORUM and
perform a write: docker exec -it Node_Z cqlsh
CONSISTENCY QUORUM use mykeyspace;
insert into users (user_id, fname, lname) values (9, 'avon',
'barksdale'); Read the data to see if the insert was
successful: select * from users; With CL = QUORUM, the
read and write were successful. What will happen with CL = ALL?
CONSISTENCY ALL insert into users (user_id,
fname, lname) values (10, 'vm', 'varga'); select *
from users; Both read and write fail. CL = ALL requires that
we read/write to three nodes (based on RF = 3), but only two nodes
are up. What happens if another node is down? Take down Node_Z and
check the status: exit docker stop Node_Z
docker exec -it Node_X nodetool status Now, set
the Consistency Level to QUORUM and perform a read and a write:
docker exec -it Node_X cqlsh CONSISTENCY
QUORUM use mykeyspace; insert into users
(user_id, fname, lname) values (11, 'morty', 'smith');
select * from users; With CL = QUORUM, the read
and write fail. Since RF=3, QUORUM means at least two nodes need to
be up. In our case, just one is. What will happen with CL = ONE?
CONSISTENCY ONE insert into users (user_id,
fname, lname) values (12, 'marlo', 'stanfield');
select * from users; With CL = QUORUM, the read and
write fail. Since RF=3, QUORUM means at least two nodes need to be
up. In our case, just one is. What do you think will happen with CL
= ONE? Check out the full
High Availability lesson and lab on ScyllaDB University, with
expected outputs, full explanation of the theory, and an option for
seamlessly running the lab within a browser, regardless of the
platform you’re using. Next Steps and Upcoming NoSQL Events A
good starting point on ScyllaDB University is
ScyllaDB Essentials – Overview of ScyllaDB and NoSQL Basics
course. There, you can find more hands-on labs like the one above,
and learn about distributed databases, NoSQL, and ScyllaDB.
ScyllaDB is backed by a vibrant community of users and developers.
If you have any questions about this blog post or about a specific
lesson, or want to discuss it, you can write on the ScyllaDB community forum.
Say hello here. The next live training events are taking place
in: An Asia-friendly
time zone event will take place on the 29th of May US/Europe,
Middle East, and Africa time zones on the 18th of June. Stay
tuned for more details! Top 5 Questions We’re Asked About Apache Cassandra® 5.0
Apache Cassandra® version 5.0 Beta 1.0 is now available in public preview on the Instaclustr Managed Platform!
Here at NetApp we are often asked about the latest releases in the open source space. This year, the biggest news is going to be the release of Apache Cassandra 5.0, and it has already garnered a lot of attention since its beta release. Apache Cassandra has been a go-to choice for distributed, highly scalable databases since its inception, and it has evolved over time, catering to the changing needs of its customers.
As we draw closer to the general availability release of Cassandra 5.0, we have been receiving many questions from our customers regarding some of the features, use cases and benefits of opting for Cassandra 5.0 and how it can help support their growing needs for scalability, performance, and advanced data analysis.
Let’s dive into the details of some of the frequently asked questions.
#1: Why should I upgrade my clusters to Cassandra 5.0?
Upgrading your clusters to Cassandra 5.0 offers several key advantages:
- New features: Cassandra 5.0 comes with a host of new and exciting features that include storage attached indexes, unified compaction strategy, and vector search. These features will significantly improve performance, optimize storage costs and pave the way for AI/ML applications.
- Stability and Bug fixes: Cassandra 5.0 brings more stability through bug fixes and added support for more guardrails. Additional information on the added guardrails can be found here.
- Apache Cassandra versions 3.0 and 3.11 will reach the end of life (EOL) with the General Availability release of Cassandra 5.0: It is standard practice that the project will no longer maintain these older versions (full details of the announcement can be found on the Apache Cassandra website). We understand the challenges this presents customers and NetApp will provide our customers with extended support for these versions for 12 months beyond the Apache Foundation project dates. Our extended support is provided to enable customers to plan their migrations with confidence. Read more about our lifecycle policies on the website.
#2: Is it possible to upgrade my workload from Cassandra 3.x to Cassandra 5.0?
You can upgrade Cassandra to any release within the next major version. For example, you can upgrade a cluster running any 3.x release to any 4.x release. However, upgrading non-adjacent major versions is not supported.
If you want to upgrade by more than one major version increment, you need to upgrade to an intermediate major version first. For example, to upgrade from a 3.x release to a 5.0 release, you must upgrade the entire cluster twice: first to 4.x (preferably the latest release: 4.1.4), then again to 5.0.
#3: What are the key changes in Apache Cassandra 5.0 compared to previous versions?
For several years, Apache Cassandra 3.x has been a major version for many customers, noted for its stability and faster import/exports. Apache Cassandra 4 focused on significantly enhancing performance with a range of enterprise-grade feature additions. However, Cassandra 5.0 introduces new features that are future-driven and open up numerous new use cases.
Let’s take a look at what’s new:
- Advanced data analysis and a pathway to AI through features such as vector search and storage-attached indexing (SAI). To learn more about SAI, visit our dedicated blog on the topic.
- Enhanced performance and
efficiency:
- The Unified Compaction Strategy and SAI directly address the need for more efficient data management and retrieval, optimizing resource utilization and improving overall system performance and efficiency.
- The “Trie-based memtables and SSTables” optimize read/write operations and storage efficiency.
- Security
and Flexibility:
- Dynamic Data Masking (DDM) enhances data privacy and security by allowing sensitive data to be masked from unauthorized access.
- While Cassandra 4.0 supported JDK 11, Cassandra 5.0 added experimental support for JDK 17, allowing its users to leverage the latest Java features and improve performance and security. It is not currently recommend to use JDK 17 in your production environment.
- The introduction of new mathematical (abs, exp, log, log10 and round) and aggregation scalar CQL functions (count, max/min, sum/avg at a collection level) has expanded Cassandra’s capabilities to handle complex data operations. These functions will help developers handle numerical operations efficiently and contribute to application performance. Read more about the enhanced Mathematical CQL capability on the Apache website.
Apache Cassandra 5.0 introduces hundreds of changes, including minor improvements to brand-new features. Visit the website for a complete list of changes.
#4: What features in Cassandra 5.0 will help me save money?
While Cassandra 5.0 promises exciting features to modernize and make you future-ready, it also includes some features that are going to help you manage your infrastructure better and eventually lower your operational costs. A couple of them include:
- Storage-attached indexes (SAI) can reduce the resource utilization associated with read operations by providing a more efficient way to index and query data, helping with managing increasing operational costs. For some use cases, smaller cluster sizes or node types may be able to achieve the same performance levels.
- The Unified Compaction Strategy optimizes the way Cassandra handles the compaction process. By automating and improving compactions, UCS can help reduce storage requirements and lower I/O overhead, resulting in lower operational costs and performance improvements. Reach out to Instaclustr Support to understand how you can adopt the Unified Compaction Strategy for your Cassandra clusters.
#5: How can Apache Cassandra help us in our AI/ML journey? With Cassandra 5.0, what are the applications and advantages of the new vector data type and similarity functions?
Some of our customers are well-ahead in their AI/ML journey, understand different use cases and know where they’d like to go, while others are still catching up.
Apache Cassandra can help you get started on your AI journey with the introduction of vector search capabilities in Cassandra 5.0. The new vector data type and similarity functions, combined with Storage Attached Indexes(SAI), are designed to handle complex and high-dimensional data.
Vector search is a powerful technique for finding relevant content within large datasets that are either structured (floats, integers, or full strings) or unstructured (such as audio, video, pictures).
This isn’t something totally new; it has been around for many years. It has evolved from a theoretical mathematical model to a key foundational technology today underlying recent AI/ML work and data storage.
Vector search plays a pivotal role in AI applications across industries by enabling efficient similarity-based querying in areas such as:
- Generative AI, Large Language Models (LLMs)
- Retrieval-Augmented Generation (RAG)
- Natural Language Processing (NLP)
- Geographical Information Systems (GIS) applications
These applications can benefit from advanced data analysis, creative content generation, semantic search and spatial analysis capabilities provided by vector search.
Vector search bridges complex data processing with practical applications, transforming the user experience and operational efficiencies across sectors. Cassandra will be an exceptional choice for vector search and AI workloads due to its distributed, highly available and scalable architecture, which is crucial for handling large datasets.
According to a report published by MarketsandMarkets:
“The demand for vector search is going to increase exponentially.
The global vector database market size is expected to grow from a little over USD 1.5 billion in 2024 to USD 4.3 billion by 2028 at a CAGR of 23.3% during the forecast period.”
As this feature is new to Cassandra 5.0, it is important to test it thoroughly before gradually integrating it into the production environment. This will allow you to explore the full capabilities of vector search while ensuring that it meets your specific needs.
Stay tuned to learn more about Vector Search in Cassandra 5.0, its prerequisites, limitations, and suitable workloads.
Instaclustr takes care of cluster upgrades for our customers to help them take advantage of the latest features without compromising stability, performance, or security. If you are not a customer yet and would like help with major version upgrades, contact our sales team.
Getting Started
- If you are an existing customer and would like to try these new features in Cassandra 5.0, you can spin up a cluster today. If you don’t have an account yet, sign up for a free trial and experience the next generation of Apache Cassandra on the Instaclustr Managed Platform.
- Read all our technical documentation here.
- Discover the 10 rules you need to know when managing Apache Cassandra.
- If you are using a relational database and are interested in vector search, check out this blog on support for pgvector, which is available as an add-on for Instaclustr for PostgreSQL services.
The post Top 5 Questions We’re Asked About Apache Cassandra® 5.0 appeared first on Instaclustr.
ScyllaDB Internal Engineering Summit in Cyprus
ScyllaDB is a remote-first company with associates working in distributed locations around the globe. We’re good at it, and we love it. Still, each year we look forward to in-person company summits to spend time together, share knowledge, and have fun. When the time comes, we say goodbye to our kids and cats and fly from all corners of the world to convene in one place. This April, we met in Limassol, a historical city on the southern coast of Cyprus. Many People, One Goal Over 120 attendees gathered at this year’s ScyllaDB Engineering Summit. With the company rapidly growing, it was a great opportunity for dozens of new associates to put faces to names, while ScyllaDB veterans could welcome the new people on board and reunite with their long-time workmates. Peyia, Paphos area with the Edro III shipwreck in the background In our everyday work life, we work in different teams, we have different roles and responsibilities. The event gathered software engineers, QA engineers, product managers, technical support engineers, developer advocates, field engineers, and more. Some of us write the code, and others make sure it’s defect-free. Some take care of the ScyllaDB roadmap, while others provide assistance to ScyllaDB customers. If we were a Git project, we would live on different branches – but there, at the Summit, they would be merged into one. Sharing knowledge, brainstorming ideas, or discussing the things we’d like to improve, we had a profound sense of a common goal – to make a cool product we’re happy with and make the users happy, too. Who-is-who team building activity On the Road to Success The goal is clear, but how do we get there? That question was the central theme of the event. The summit agenda was filled with technical sessions, each with ample time for Q&A. They were a great platform for engaging in discussions and brainstorming, as well as an opportunity to get an insight into other teams’ areas of work. The speakers covered a wide range of topics, including: ScyllaDB roadmap Security features Data distribution with tablets Strong data consistency with Raft Observability and metrics Improving customer experience Streamlining the management of our GitHub projects And many more Dor Laor kicking off the Summit Let’s Get The Party Started The sessions were inspiring and fruitful, but hey, we were in Cyprus! And what is Cyprus famous for if not for its excellent food and wine, beautiful beaches, and holiday vibes? We could enjoy all those things at company dinners in beautifully located Cypriot restaurants – and at amazing beaches or quiet coves. One of the many amazing beachside meals Then came the party. Live music and a DJ putting on all-time hit songs got the crowd going. Rumor has it that engineers don’t know how to party. Please don’t believe it 🙂 Party time! Off-Road Adventure Mid-week, we took a break to recharge the batteries and went on an off-road jeep safari. Fifteen 4x4s took us on a scenic tour along the sea-coast of Paphos, where we could admire beautiful views. Setting off on the jeep safari adventure While enjoying a bumpy ride, we learned a lot about Cyprus’ history and culture from the jeep drivers, who willingly answered all our questions. From time to time, we stopped to see masterpieces of nature, such as a stunning gorge, waterfalls, and the Blue Lagoon, our favorite, where we swam in crystal-clear water. A view over the lagoons, Akamas Peninsula Together as One It was an eventful Summit filled with many memorable moments. It inspired us, fed our spirits, and gave us some food for thought. But most importantly, it brought us together and let us enjoy a shared sense of purpose. When the Summit was coming to a close, we could genuinely feel that we were one team. When we all got safely home, our CEO emailed us to say, “All of our previous summits were great, but this felt even better. The level of teamwork is outstanding, and many companies can just envy what we have here.” I couldn’t agree more. Want to Join our Team? ScyllaDB has a number of open positions worldwide, including many remote positions across Engineering, QA & Automation, Product, and more. Check out the complete list of open positions on our Careers page. Join the ScyllaDB Team!Node throughput Benchmarking for Apache Cassandra® on AWS, Azure and GCP
At NetApp, we are often asked for comparative benchmarking of our Instaclustr Managed Platform across various cloud providers and the different node sizes we offer.
For Apache Cassandra® on the Instaclustr Managed Platform, we have recently completed an extensive benchmarking exercise that will help our customers evaluate the node types to use and the differing performance between cloud providers.
Each cloud service provider is continually introducing new and improved nodes, which we carefully select and curate to provide our customers with a range of options to suit their specific workloads. The results of these benchmarks can assist you in evaluating and selecting the best node sizes that provide optimal performance at the lowest cost.
How Should Instaclustr Customers Use the Node Benchmark Data?
Instaclustr node benchmarks provide throughput for each node performed under the same test conditions, serving as valuable performance metrics for comparison.
As with any generic benchmarking results, for different data models or application workload, the performance may vary from the benchmark. Instaclustr node benchmarks do not account for specific configurations of the customer environment and should only be used to compare the relative performance of node sizes.
Instaclustr recommends customers complete testing and data modelling in their own environment across a selection of potential nodes.
Test Objective
Cassandra Node Benchmarking creates a Performance Metric value for each General Availability (GA) node type that is available for Apache Cassandra across AWS, GCP, and Azure AZ. Each node is benchmarked before being released to General Availability. The tests ensure that all nodes will deliver sufficient performance based on their configuration.
All Cassandra production nodes Generally Available on the Instaclustr platform are stress-tested to find the operational capacity of the nodes. This is accomplished by measuring throughput to find the highest ops rate the test cluster can achieve without performance degradation.
Methodology
We used the following configuration to conduct this benchmarking:
- Cassandra-stress tool
- QUORUM consistency level for data operations
- 3-node cluster using Cassandra 4.0.10 with each node in a separate rack within a single datacenter
On each node size, we run the following testing procedure:
- Fill Cassandra with enough records to approximate 5x the system memory of the node using the “small” size writes. This is done to ensure that the entire data model is not sitting in memory, and to give a better representation of a production cluster.
- Allow the cluster to finish all compactions. This is done to ensure that all clusters are given the same starting point for each test run and to make test runs comparable and verifiable.
- Allow compactions to finish between each step.
- Perform multiple stress tests on
the cluster, increasing the number of operations per second
for
each test, until we
overload it. The cluster will be
considered overloaded if one of three conditions is met:
- The latency of the operation is above the provided threshold. This tells us that the cluster cannot keep up with the current load and is unable to respond quickly.
- If a node has more than 20 pending compactions a minute after the test completes. This tells us that the cluster is not keeping up with compactions, and this load is not sustainable in the long term.
- The CPU load is above the provided threshold. This is the reason that we pass the number of cores into the Cassandra Stress Tool.
- Using this definition of
“overloaded”, the following tests are run
to measure
maximum throughput:
- Perform a combination of reads and write operations in 30-minute test runs. The combination of writes, simple reads, and range reads is at a rate of 10:10:1, increasing threads until we reach a read median latency of 20ms indicating if a mixed workload throughput has changed.
Results
Following this approach, the tables below show the results we measured on the different providers and different node sizes we offer.
| Node Type (Node Size Used) | Ram / Cores | Result (MixedOPS) |
|---|---|---|
| t4g.small (CAS-DEV-t4g.small-30) | 2 GiB / 2 | 728* |
| t4g.medium (CAS-DEV-t4g.medium-80) | 4 GiB / 2 | 3,582 |
| r6g.medium (CAS-PRD-r6g.medium-120) | 8 GiB / 1 | 1,849 |
| m6g.large (CAS-PRD-m6g.large-120) | 8 GiB / 2 | 2,144 |
| r6g.large (CAS-PRD-r6g.large-250) | 16 GiB / 2 | 3,117 |
| r6g.xlarge (CAS-PRD-r6g.xlarge-400) | 32 GiB / 4 | 16,653 |
| r6g.2xlarge (CAS-PRD-r6g.2xlarge-800) | 64 GiB / 8 | 36,494 |
| r6g.4xlarge (CAS-PRD-r6g.4xlarge-1600) | 128 GiB / 16 | 62,195 |
| r7g.medium (CAS-PRD-r7g.medium-120) | 8 GiB / 1 | 2,527 |
| m7g.large (CAS-PRD-m7g.large-120) | 8 GiB / 2 | 2,271 |
| r7g.large (CAS-PRD-r7g.large-120) | 16 GiB / 2 | 3,039 |
| r7g.xlarge (CAS-PRD-r7g.xlarge-400) | 32 GiB / 4 | 20,897 |
| r7g.2xlarge (CAS-PRD-r7g.2xlarge-800) | 64 GiB / 8 | 39,801 |
| r7g.4xlarge (CAS-PRD-r7g.4xlarge-800) | 128 GiB / 16 | 70,880 |
| c5d.2xlarge (c5d.2xlarge-v2) | 16 GiB / 8 | 26,494 |
| c6gd.2xlarge (CAS-PRD-c6gd.2xlarge-441) | 16 GiB / 8 | 27,066 |
| is4gen.xlarge (CAS-PRD-is4gen.xlarge-3492) | 24 GiB / 4 | 19,066 |
| is4gen.2xlarge (CAS-PRD-is4gen.2xlarge-6984) | 48 GiB / 8 | 34,437 |
| im4gn.2xlarge (CAS-PRD-im4gn.2xlarge-3492) | 32 GiB / 8 | 31,090 |
| im4gn.4xlarge (CAS-PRD-im4gn.4xlarge-6984) | 64 GiB / 16 | 59,410 |
| i3en.xlarge (i3en.xlarge) | 32 GiB / 4 | 19,895 |
| i3en.2xlarge (CAS-PRD-i3en.2xlarge-4656) | 64 GiB / 8 | 40,796 |
| i3.2xlarge (i3.2xlarge-v2) | 61 GiB / 8 | 24,184 |
| i3.4xlarge (CAS-PRD-i3.4xlarge-3538) | 122 GiB / 16 | 42,234 |
* Nodes overloaded with the stress test started dropping out
| Node Type (Node Size Used) | Ram / Cores | Result (MixedOPS) |
|---|---|---|
| Standard_DS12_v2 (Standard_DS12_v2-512-an) | 28 GiB / 4 | 23,878 |
| Standard_DS2_v2 (Standard_DS2_v2-256-an) | 7 GiB / 2 | 1,535 |
| L8s_v2 (L8s_v2-an) | 64 GiB / 8 | 24,188 |
| Standard_L8s_v3 (CAS-PRD-Standard_L8s_v3-1788) | 64 GiB / 8 | 33,990 |
| Standard_DS13_v2 (Standard_DS13_v2-2046-an) | 56 GiB / 8 | 37,908 |
| D15_v2 (D15_v2-an) | 140 GiB / 20 | 68,226 |
| Standard_L16s_v2 (CAS-PRD-Standard_L16s_v2-3576-an) | 128 GiB / 16 | 33,969 |
| Node Type (Node Size Used) | Ram / Cores | Result (MixedOPS) |
|---|---|---|
| n1-standard-1 (CAS-DEV-n1-standard-1-5) | 3.75 GiB / 1 | No data* |
| n1-standard-2 (CAS-DEV-n1-standard-2-80) | 7.5 GiB / 2 | 3,159 |
| t2d-standard-2 (CAS-PRD-t2d-standard-2-80) | 8 GiB / 2 | 6,045 |
| n2-standard-2 (CAS-PRD-n2-standard-2-120) | 8 GiB / 2 | 4,199 |
| n2-highmem-2 (CAS-PRD-n2-highmem-2-250) | 16 GiB / 2 | 5,520 |
| n2-highmem-4 (CAS-PRD-n2-highmem-4-400) | 32 GiB / 8 | 19,893 |
| n2-standard-8 (cassandra-production-n2-standard-8-375) | 32 GiB / 8 | 37,437 |
| n2-highmem-8 (CAS-PRD-n2-highmem-8-800) | 64 GiB / 8 | 38,139 |
| n2-highmem-16 (CAS-PRD-n2-highmem-16-800) | 128 GiB / 16 | 73,918 |
* Cannot be tested due to the fill data requirement being greater than the available disk space
Conclusion: What We Discovered
In general, we see that clusters with more processing power (CPUs and RAM) produce higher throughput as expected. Some of the key takeaways include:
- When it comes to the
price-to-performance ratio of Cassandra, there is a sweet spot
around the XL/2XL node size (eg
r6g.xlarge or r6g.2xlarge).
- Moving from L to XL nodes, doubles performance, and moving from XL to 2XL, almost always doubles performance again.
- However, moving from 2XL to 4XL, the increase in performance is less than double. This is expected as you move from a memory-constrained state to a state with more resources than can be utilized. These findings are specific to Cassandra.
- Different node families are tailored for workloads, significantly impacting their performance. Hence, nodes should be selected based on workload requirements and use cases.
Overall, these benchmarks provide an indication of potential throughput for different environments and instance sizes. Performance can vary significantly depending on individual use cases, and we always recommend benchmarking with your own specific use case prior to production deployment.
The easiest way to see all the new node offerings for your provider is to log into our Console. We ensure that you have access to the latest instance types by supporting different node types from each cloud provider on our platform to help you get high performance at reduced costs.
Do you know that R8g instances from AWS deliver up to 30% better performance than Graviton3-based R7g instances? Keep an eye out, as we will make these new instances available on our platform as soon as they are released for general availability.
If you are interested in migrating your existing Cassandra clusters to the Instaclustr Managed Platform, our highly experienced Technical Operations team can provide all the assistance you need. We have built several tried-and-tested node replacement strategies to provide zero-downtime, non-disruptive migrations. Read our Advanced Node Replacement blog for more details on one such strategy.
If you want to know more about this benchmarking or need clarification on when to use which instance type for Cassandra, reach out to our Support team (if you are an existing customer) or contact our Sales team. Our support team can assist you in resizing your existing clusters. Alternatively, you can use our in-place data-center resizing feature to do it on your own.
The post Node throughput Benchmarking for Apache Cassandra® on AWS, Azure and GCP appeared first on Instaclustr.
How to Build a Real-Time CDC pipeline with ScyllaDB & Redpanda
A step-by-step tutorial to capturing changed data for high-throughput, low-latency applications, using Redpanda and ScyllaDB This blog is a guest post by Kovid Rathee. It was first published on the Redpanda blog. CDC is a methodology for capturing change events from a source database. Once captured, the change events can be used for many downstream use cases, such as triggering events based on specific conditions, auditing, and analytics. ScyllaDB is a distributed, wide-column NoSQL database known for its ultra-fast performance as it’s written in C++ to make the best use of the low-level Linux primitives, which helps attain much better I/O. It’s also an excellent alternative to DynamoDB as well as a popular alternative to Apache Cassandra. ScyllaDB’s modern approach to NoSQL and its architecture supporting data-intensive and low-latency applications make it an excellent choice for many applications. ScyllaDB shines when you need it to respond and scale super fast. Redpanda is a source available (BSL), Apache Kafka®-compatible, streaming data platform designed from the ground up to be lighter, faster, and simpler to operate. It employs a single binary architecture, free from ZooKeeper™ and JVMs, with a built-in Schema Registry and HTTP Proxy. Since both ScyllaDB and Redpanda are purpose-built for data-intensive applications, it makes perfect sense to connect the two. This post will take you through setting up a CDC integration between ScyllaDB and Redpanda, using a Debezium CDC connector that’s compatible with Kafka Connect. Let’s dig in. Note: Want an in-depth look at using Rust + Redpanda + ScyllaDB to build high-performance systems for real-time data streaming? Join our interactive Masterclass on May 15. You will learn how to: Understand core concepts for working with event-driven architectures Build a high performance streaming app with Rust Avoid common mistakes that surface in real-world systems at scale Evaluate the pros, cons, and best use cases for different event streaming options How to build a real-time CDC pipeline between ScyllaDB and Redpanda This tutorial will first guide you through the process of setting up ScyllaDB and Redpanda. You’ll create a standalone Kafka Connect cluster and incorporate the ScyllaDB CDC Connector JAR files as plugins. This will allow you to establish a connection between ScyllaDB and Kafka Connect. This tutorial uses ScyllaDB’s CDC quickstart guide, which takes an arbitraryorders table for an e-commerce business and streams
data from that to a sink using the Kafka Connect-compatible
Debezium connector. The following image depicts the simplified
architecture of the setup: Connecting ScyllaDB and Redpanda using
Kafka Connect The orders table receives new orders and
updates on previous orders. In this example, you’ll insert a few
simple orders with an order_id, a
customer_id, and a product. You’ll first
insert a few records in the orders table and then
perform a change on one of the records. All the data, including new
records, changes, and deletes, will be available as change events
on the Redpanda topic you’ve tied to the ScyllaDB
orders table. Prerequisites To complete this tutorial,
you’ll need the following: Docker Engine and
Docker
Compose A
Redpanda instance on Docker A ScyllaDB
instance running on Docker
ScyllaDB Kafka Connect drivers The jq CLI tool The
rpk
CLI tool
Note: The operating system used in this tutorial is macOS.1. Run and configure ScyllaDB After installing and starting Docker Engine on your machine, execute the following Docker command to get ScyllaDB up and running:
docker run --rm -ti \ -p
127.0.0.1:9042:9042 scylladb/scylla \ --smp 1 --listen-address
0.0.0.0 \ --broadcast-rpc-address 127.0.0.1 This command
will spin up a container with ScyllaDB, accessible on 127.0.0.1 on
port 9042. To check ScyllaDB’s status, run the following command
that uses the ScyllaDB
nodetool utility: docker exec -it 225a2369a71f nodetool
status This command should give you an output that looks
something like the following: Datacenter: datacenter1
======================= Status=Up/Down |/
State=Normal/Leaving/Joining/Moving -- Address Load Tokens Owns
Host ID Rack UN 0.0.0.0 256 KB 256 ?
2597950d-9cc6-47eb-b3d6-a54076860321 rack1 The
UN at the beginning of the table output means
Up and Normal. These two represent the
cluster’s status and state, respectively. 2. Configure CDC on
ScyllaDB To set up CDC on ScyllaDB, you first need to log in to the
cluster using the cqlsh CLI. You can do that using the
following command: docker exec -it 225a2369a71f cqlsh
If you’re able to log in successfully, you’ll see the following
message: Connected to at 0.0.0.0:9042. [cqlsh 5.0.1 |
Cassandra 3.0.8 | CQL spec 3.3.1 | Native protocol v4] Use HELP for
help. cqlsh> Keyspaces are high-level containers for all
the data in ScyllaDB. A keyspace in ScyllaDB is conceptually
similar to a schema or database in MySQL. Use the following command
to create a new keyspace called quickstart_keyspace
with SimpleStrategy replication and a
replication_factor of 1: CREATE KEYSPACE
quickstart_keyspace WITH REPLICATION = {'class': 'SimpleStrategy',
'replication_factor': 1}; Now, use this keyspace for further
CQL commands: USE quickstart_keyspace; Please note
that the SimpleStrategy replication class is not
recommended for production use. Instead, you should use the
NetworkTopologyStrategy replication class. You can
learn more about replication methodologies from
ScyllaDB University. 3. Create a table Use the following CQL
statement to create the orders table described at the
beginning of the tutorial: CREATE TABLE orders( customer_id
int, order_id int, product text, PRIMARY KEY(customer_id,
order_id)) WITH cdc = {'enabled': true}; This statement
creates the orders table with a composite primary key
consisting of customer_id and order_id.
The orders table will be CDC-enabled. ScyllaDB stores
table data in a base table, but when you enable CDC on that table,
an additional table that captures all the changed data is created
as well. That table is called a
log table. 4. Insert a few initial records Populate a few
records for testing purposes: INSERT INTO
quickstart_keyspace.orders(customer_id, order_id, product) VALUES
(1, 1, 'pizza'); INSERT INTO
quickstart_keyspace.orders(customer_id, order_id, product) VALUES
(1, 2, 'cookies'); INSERT INTO
quickstart_keyspace.orders(customer_id, order_id, product) VALUES
(1, 3, 'tea'); During the course of the tutorial, you’ll
insert three more records and perform an update on one record,
totaling seven events in total, four of which are change events
after the initial setup. 5. Set up Redpanda Use the
docker-compose.yaml file in the
Redpanda Docker quickstart tutorial to run the following
command: docker compose up -d A Redpanda cluster and a
Redpanda console will be up and running after a brief wait. You can
check the status of the Redpanda cluster using the following
command: docker exec -it redpanda-0 rpk cluster info
The output of the command should look something like the following:
CLUSTER ======= redpanda.3fdc3646-9c9d-4eff-b5d6-854093a25b67
BROKERS ======= ID HOST PORT 0* redpanda-0 9092
Before setting up an integration between ScyllaDB and Redpanda,
check if all the Docker containers you have spawned are running by
using the following command: docker ps --format "table
{{.Image}}\t{{.Names}}\t{{.Status}}\t{{.Ports}}" Look for
the STATUS column in the table output: IMAGE
NAMES STATUS PORTS scylladb/scylla gifted_hertz Up 8 hours 22/tcp,
7000-7001/tcp, 9160/tcp, 9180/tcp, 10000/tcp,
127.0.0.1:9042->9042/tcp
docker.redpanda.com/vectorized/console:v2.2.4 redpanda-console Up 9
hours 0.0.0.0:8080->8080/tcp
docker.redpanda.com/redpandadata/redpanda:v23.1.8 redpanda-0 Up 9
hours 8081-8082/tcp, 0.0.0.0:18081-18082->18081-18082/tcp,
9092/tcp, 0.0.0.0:19092->19092/tcp,
0.0.0.0:19644->9644/tcp If these containers are up and
running, you can start setting up the integration. 6. Set up Kafka
Connect Download and install Kafka using the following sequence of
commands: # Extract the binaries wget
https://downloads.apache.org/kafka/3.4.0/kafka_2.13-3.4.0.tgz
&& tar -xzf kafka_2.13-3.4.0.tgz && cd
kafka_2.13-3.4.0.properties files will be kept in the
kafka_2.13-3.4.0/config folder in your download
location. To use Kafka Connect, you must configure and validate two
.properties files. You can name these files anything.
In this tutorial, the two files are called
connect-standalone.properties and
connector.properties. The first file contains the
properties for the standalone Kafka Connect instance. For this
file, you will only change the default values of two variables: The
default value for the bootstrap.servers variable is
localhost:9092. As you’re using Redpanda and its
broker is running on port 19092, you’ll replace the default value
with localhost:19092. Find the plugin path directory
for your Kafka installation and set the plugin.path
variable to that path. In this case, it’s
/usr/local/share/kafka/plugins. This is where your
ScyllaDB
CDC Connector JAR file will be copied. The comment-stripped
version of the connect-standalone.properties file
should look like the following:
bootstrap.servers=localhost:19092
key.converter.schemas.enable=true
value.converter.schemas.enable=true
offset.storage.file.filename=/tmp/connect.offsets
offset.flush.interval.ms=10000
plugin.path=/usr/local/share/kafka/plugins The second
.properties file will contain settings specific to the
ScyllaDB connector. You need to change the
scylla.cluster.ip.addresses variable to
127.0.0.1:9042. The connector.properties
file should then look like the following: name =
QuickstartConnector connector.class =
com.scylladb.cdc.debezium.connector.ScyllaConnector key.converter =
org.apache.kafka.connect.json.JsonConverter value.converter =
org.apache.kafka.connect.json.JsonConverter
scylla.cluster.ip.addresses = 127.0.0.1:9042 scylla.name =
QuickstartConnectorNamespace scylla.table.names =
quickstart_keyspace.orders Using both the
.properties files, go to the Kafka installation
directory and run the connect-standalone.sh script
with the following command: bin/connect-standalone.sh
config/connect-standalone.properties
config/connector.properties When you created the
orders table, you enabled CDC, which means that
there’s a log table with all the records and changes. If the Kafka
Connect setup is successful, you should now be able to consume
these events using the rpk CLI tool. To do so, use the
following command: rpk topic consume --brokers
'localhost:19092'
QuickstartConnectorNamespace.quickstart_keyspace.orders | jq
. The output should result in the following three records,
as shown below: { "topic":
"QuickstartConnectorNamespace.quickstart_keyspace.orders", "key":
"{\"schema\":{\"type\":\"struct\",\"fields\":[{\"type\":\"int32\",\"optional\":true,\"field\":\"customer_id\"},{\"type\":\"int32\",\"optional\":true,\"field\":\"order_id\"}],\"optional\":false,\"name\":\"QuickstartConnectorNamespace.quickstart_keyspace.orders.Key\"},\"payload\":{\"customer_id\":1,\"order_id\":1}}",
"value": …output omitted… "timestamp": 1683357426891, "partition":
0, "offset": 0 } { "topic":
"QuickstartConnectorNamespace.quickstart_keyspace.orders", "key":
"{\"schema\":{\"type\":\"struct\",\"fields\":[{\"type\":\"int32\",\"optional\":true,\"field\":\"customer_id\"},{\"type\":\"int32\",\"optional\":true,\"field\":\"order_id\"}],\"optional\":false,\"name\":\"QuickstartConnectorNamespace.quickstart_keyspace.orders.Key\"},\"payload\":{\"customer_id\":1,\"order_id\":2}}",
"value": …output omitted… "timestamp": 1683357426898, "partition":
0, "offset": 1 } { "topic":
"QuickstartConnectorNamespace.quickstart_keyspace.orders", "key":
"{\"schema\":{\"type\":\"struct\",\"fields\":[{\"type\":\"int32\",\"optional\":true,\"field\":\"customer_id\"},{\"type\":\"int32\",\"optional\":true,\"field\":\"order_id\"}],\"optional\":false,\"name\":\"QuickstartConnectorNamespace.quickstart_keyspace.orders.Key\"},\"payload\":{\"customer_id\":1,\"order_id\":3}}",
"value": …output omitted… "timestamp": 1683357426898, "partition":
0, "offset": 2 } If you get a similar output, you’ve
successfully integrated ScyllaDB with Redpanda using Kafka Connect.
Alternatively, you can go to the Redpanda console hosted on
localhost:8080 and see if the topic corresponding to
the ScyllaDB orders table is available: You can now
test whether data changes to the orders table can
trigger CDC. 7. Capture Change Data (CDC) from ScyllaDB To test CDC
for new records, insert the following two records in the
orders table using the cqlsh CLI:
INSERT INTO quickstart_keyspace.orders(customer_id, order_id,
product) VALUES (1, 4, 'chips'); INSERT INTO
quickstart_keyspace.orders(customer_id, order_id, product) VALUES
(1, 5, 'lollies'); If the insert is successful, the
rpk topic consume command will give you the following
additional records: { "topic":
"QuickstartConnectorNamespace.quickstart_keyspace.orders", "key":
"{\"schema\":{\"type\":\"struct\",\"fields\":[{\"type\":\"int32\",\"optional\":true,\"field\":\"customer_id\"},{\"type\":\"int32\",\"optional\":true,\"field\":\"order_id\"}],\"optional\":false,\"name\":\"QuickstartConnectorNamespace.quickstart_keyspace.orders.Key\"},\"payload\":{\"customer_id\":1,\"order_id\":4}}",
"value": …output omitted… "timestamp": 1683357768358, "partition":
0, "offset": 3 } { "topic":
"QuickstartConnectorNamespace.quickstart_keyspace.orders", "key":
"{\"schema\":{\"type\":\"struct\",\"fields\":[{\"type\":\"int32\",\"optional\":true,\"field\":\"customer_id\"},{\"type\":\"int32\",\"optional\":true,\"field\":\"order_id\"}],\"optional\":false,\"name\":\"QuickstartConnectorNamespace.quickstart_keyspace.orders.Key\"},\"payload\":{\"customer_id\":1,\"order_id\":5}}",
"value": …output omitted… "timestamp": 1683358068355, "partition":
0, "offset": 4 } You’ll now insert one more record with the
product value of pasta: INSERT INTO
quickstart_keyspace.orders(customer_id, order_id, product) VALUES
(1, 5, 'pasta'); Later on, you’ll change this value with an
UPDATE statement to spaghetti and trigger
a CDC update event. The newly inserted record should be visible
with your rpk topic consume command: { "topic":
"QuickstartConnectorNamespace.quickstart_keyspace.orders", "key":
"{\"schema\":{\"type\":\"struct\",\"fields\":[{\"type\":\"int32\",\"optional\":true,\"field\":\"customer_id\"},{\"type\":\"int32\",\"optional\":true,\"field\":\"order_id\"}],\"optional\":false,\"name\":\"QuickstartConnectorNamespace.quickstart_keyspace.orders.Key\"},\"payload\":{\"customer_id\":1,\"order_id\":6}}",
"value": …output omitted… "timestamp": 1683361158363, "partition":
0, "offset": 5 } Now, execute the following
UPDATE statement and see if a CDC update event is
triggered: UPDATE quickstart_keyspace.orders SET product =
'spaghetti' WHERE order_id = 6 and customer_id = 1; After
running this command, you’ll need to run the rpk topic
consume command to verify the latest addition to the
QuickstartConnectorNamespace.quickstart_keyspace.orders
topic. The change event record should look like the following:
{ "topic":
"QuickstartConnectorNamespace.quickstart_keyspace.orders", "key":
"{\"schema\":{\"type\":\"struct\",\"fields\":[{\"type\":\"int32\",\"optional\":true,\"field\":\"customer_id\"},{\"type\":\"int32\",\"optional\":true,\"field\":\"order_id\"}],\"optional\":false,\"name\":\"QuickstartConnectorNamespace.quickstart_keyspace.orders.Key\"},\"payload\":{\"customer_id\":1,\"order_id\":6}}",
"value": …output omitted… "timestamp": 1683362868372, "partition":
0, "offset": 6 } 8. Access the captured data using Redpanda
Console When you spin up Redpanda using Docker Compose, it creates
a Redpanda cluster and a Redpanda
Console. Using the console, you can visually inspect topics and
messages. After all the change events on the orders
table are captured, you can go to the Redpanda Console and select
the
QuickstartConnectorNamespace.quickstart_keyspace.orders
topic to see the messages, as shown below: Redpanda console showing
all events in the topic You can also see the schema details, the
payload, and other event metadata in the event message, as shown
below: Redpanda Console showing details of one of the events You’ve
now successfully set up CDC between ScyllaDB and Redpanda, consumed
change events from the CLI, and accessed the same messages using
the Redpanda Console! Conclusion This tutorial introduced you to
ScyllaDB and provided step-by-step instructions to set up a
connection between ScyllaDB and Redpanda for capturing changed
data. Messaging between systems is one of the most prominent ways
to create asynchronous, decoupled applications. Bringing CDC events
to Redpanda allows you to integrate various systems. Using this CDC
connection, you can consume data from Redpanda for various
purposes, such as triggering workflows based on change events,
integrating with other data sources, and creating a data lake. By
following the tutorial and using the
supporting GitHub repository, you can easily get started with
CDC. To explore Redpanda, check the documentation and browse
the Redpanda blog for more
tutorials. If you have any questions or want to chat with the team,
join the Redpanda Community on
Slack. Likewise, if you want to learn more about ScyllaDB, see
our documentation, visit ScyllaDB University (free), and feel free
to reach out
to the team. Storage Attached Indexing: A Key New Feature in Apache Cassandra® 5.0
Apache Cassandra® version 5.0 Beta 1.0 is now available in public preview on the Instaclustr Managed Platform!
Here at NetApp, we’re excited to see the new Apache Cassandra version 5.0 release and the extended functionality that has been introduced. We have been testing the newest features that come along with this version, and in particular, getting to understand the latest secondary indexing architecture with Storage Attached Indexing (SAI).
Cassandra has always offered a secondary index, which can extend your read options by querying the database with values that are not the primary key. However, the overhead of servicing these queries across a distributed system has always been a concern due to the time and resource costs involved.
Storage Attached Indexes addresses these challenges by reducing storage overhead and enhancing query performance through optimizations on index storage and access paths. So, you can see why we’re keen to work with Storage Attached Indexing and help our customers get the most out of what is already a pretty amazing big data database.
What is Secondary Indexing and why does it matter to my Cassandra cluster?
Cassandra is designed to manage writes and reads at a large scale, but read operations– when querying for data on non-primary keys–are resource–intensive and more complex than what you find when querying in a ‘traditional’ relational database. Indexing is a technique used to quickly access and retrieve entries in a database and is typically adopted by developers to optimize read performance.
With Cassandra’s secondary index, developers have the option to configure query data on specific values over and above the primary key. Secondary Indexes solve the problem of querying columns that are not part of the primary key.
Essentially, developers choose to use a secondary index with Cassandra clusters to expand the flexibility of queries that they want to run across their data. Without a secondary index, Cassandra is very limited to what can be queried beyond the primary key. Instaclustr offers customers reliable and scalable systems data layer technologies to manage data at scale with the least hassle and lowest cost.
Having improved data access and retrieval comes with additional considerations. Secondary indexes rely on local indexing, which means index data is co-located with the source data on the same nodes. When retrieving data using only an indexed column, Cassandra doesn’t have a way to determine which nodes have the necessary data. Consequently, it ends up querying all the nodes in the cluster.
This process can cause increased data transfer, high latency, and a potential increase in costs, especially if the cluster has many nodes. As with adopting any new feature, it’s recommended to test secondary indexes with your application to ensure cluster performance is acceptable. Read here to understand more about the cost and benefits of Cassandra Filtering and Partition Keys.
What’s Different for Secondary Indexing in Cassandra 5.0?
Over the years, the Apache Cassandra community has been evolving functionality to get the most efficient and effective method for reading the vast quantities of data that the database can manage.
The Cassandra 5.0 Storage Attached Index (SAI) functionality has evolved from previous Secondary Indexes (2i) and SSTable Attached Secondary Index (SASI); the SAI architecture has been designed to operate as a native database operation, reducing query latency and resource usage, while maintaining the scalability, fault tolerance and performance that Cassandra is known for.
Design improvements with SAI include:
- Enables vector search through the new storage-attached index (SAI) called “VectorMemtableIndex”
- Lower disk usage: compared to SASI, SAI doesn’t create ngrams (contiguous subset of a longer sequence) for every term, saving a significant amount of disk space. Additionally, SAI eliminates the need to duplicate an entire table with a new partition key.
- Simplified queries: newly introduced query syntax eliminates the need to create an SSTable for each query pattern. This means multiple indexes on one table, rather than multiple tables for multiple query patterns.
Storage Attached Indexing and Vector Search
Another exciting and significant enhancement delivered by Cassandra 5.0 is support for a Vector CQL data type. Support for this new data type means that Cassandra will handle and store embedding vectors as arrays of floating-point numbers. When coupled with Storage–Attached Indexing, the vector CQL data type introduced in Cassandra 5.0 enables Cassandra to support AI/ML workloads.
Cassandra natively manages scalability for large datasets and is the obvious choice to handle large volumes and accelerated growth of vector data as organization’s explore and establish AI/ML capabilities.
We’re excited to work with our Instaclustr customers and support them as they get started on the AI/ML journey, making the right choices at the beginning of that journey to get the best value for their business.
Getting Started with Storage Attached Indexing
At Instaclustr, we make it easy to provision and manage the operations of your data infrastructure so you can focus on accelerating development of your business applications. Trial the new Storage Attached Index feature with Apache Cassandra today and set up a non-production cluster using the Instaclustr console. Click here for a guide on how to provision an Apache Cassandra 5.0 Beta 1.0 cluster.
If you have any issues or questions about provisioning your cluster, please contact Instaclustr Support at any time.
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