Using Salting to Lower Latency for Large Blobs in ScyllaDB

25 June 2026, 3:00 pm by ScyllaDB

A modified salting technique that cuts P99 write latency 22x for large blobs Storing huge blobs in any database has always been, and still is, very challenging. Large allocations required for storing, reading, compacting, and repairing such cells always create significant pressure on the memory allocation sub-system. In addition, receiving a write request or sending a read response with a huge payload on a shared connection creates a “head of line” issue impacting the latency of other requests. This is true for every database! Consequently, by splitting the blob into smaller chunks and processing them in parallel, we can achieve latencies comparable to a single chunk read/write operation. Naturally, when all your data consists of huge blobs, you are probably not going to use CQL or SQL databases to store them. You will use S3-like storage for blobs and will use CQL/SQL DB to store references to those blobs. However, if your data is mostly reasonably small but has a small part of the population that are huge blobs, you may want to be able to serve both small and large blobs from the same database. While working with ScyllaDB, we found that a modified salting technique can address the latency impact of storing large blobs. In this post, we present that salting technique, then explain when/how to apply it. Background: Large Blobs in ScyllaDB For a better idea of how storing large blobs impacts performance, let’s look at an example. In our testing of ScyllaDB version 2026.1.1 with cassandra-stress tool, we observed that writing key-value rows with a 60MB blob cell results in an average latency of about 568ms and P99 latencies of 1.4s. In contrast, writing K/V data of 1MB yields an average latency of 2.2ms, with a P99 of approximately 4.5ms. When writing 60MB cells, ScyllaDB could not go any faster because its memory management system was totally saturated. Below are the results of the 60MB cell test (with a single i8g.4xlarge node): Results: Op rate : 18 op/s [WRITE: 18 op/s] Partition rate : 18 pk/s [WRITE: 18 pk/s] Row rate : 18 row/s [WRITE: 18 row/s] Latency mean : 567.6 ms [WRITE: 567.6 ms] Latency median : 497.0 ms [WRITE: 497.0 ms] Latency 95th percentile : 1087.4 ms [WRITE: 1,087.4 ms] Latency 99th percentile : 1436.5 ms [WRITE: 1,436.5 ms] Latency 99.9th percentile : 1874.9 ms [WRITE: 1,874.9 ms] Latency max : 1995.4 ms [WRITE: 1,995.4 ms] Total partitions : 1,000 [WRITE: 1,000] Total errors : 0 [WRITE: 0] Total GC count : 0 Total GC memory : 0.000 KiB Total GC time : 0.0 seconds Avg GC time : NaN ms StdDev GC time : 0.0 ms Total operation time : 00:00:55 And here are the results of writes of 1MB cells with the same rate byte-to-byte with the 60MB execution above: Op rate : 1,061 op/s [WRITE: 1,080 op/s] Partition rate : 1,061 pk/s [WRITE: 1,080 pk/s] Row rate : 1,061 row/s [WRITE: 1,080 row/s] Latency mean : 2.2 ms [WRITE: 2.2 ms] Latency median : 2.0 ms [WRITE: 2.0 ms] Latency 95th percentile : 2.8 ms [WRITE: 2.8 ms] Latency 99th percentile : 4.5 ms [WRITE: 4.5 ms] Latency 99.9th percentile : 15.0 ms [WRITE: 15.0 ms] Latency max : 41.6 ms [WRITE: 41.6 ms] Total partitions : 60,000 [WRITE: 60,000] Total errors : 0 [WRITE: 0] Total GC count : 0 Total GC memory : 0.000 KiB Total GC time : 0.0 seconds Avg GC time : NaN ms StdDev GC time : 0.0 ms Total operation time : 00:00:56 The 60MB blob results are suboptimal for high-performance requirements. However, 1MB results show that if we can split the blob into smaller chunks and write/read them in parallel we can achieve latencies close to a single chunk read/write operation. Perhaps salting can help us achieve this? Classic Salting Technique The classic “salting” technique, used to break down large partitions consisting of too many rows, introduces an additional “salt” column to the partition key. It selects a random value from a known range (e.g., an integer between 0 and 99) to store the next row. This will distribute what once was a single large partition for a key KEY1 into 100 smaller partitions with partition keys (KEY1, 0), (KEY1, 1) …, (KEY1, 99) each of about 1/100 the size of the original one. The primary drawback of this technique for large partitions is the necessity of using “salting” for every row, as the system does not inherently know if a row belongs to a large partition. Consequently, reading data for any original key KEYn requires reading all 100 partitions (KEYn, k), where k=0, 1, …, 99. And this may be very wasteful because large partitions normally represent a very small part of the total partition population. Similarly, large blobs typically represent only a small fraction of the total blob population. Another “weak spot” of the classic “salting” is that you can’t reduce the SALT cardinality — you can only increase it. This means that if the size of your large partitions got smaller, you would still need to use the same “salt” cardinality you already used before. Modified Salting Technique for Storing Blobs We found that improving the original “salting” algorithm for a blob case can eliminate both of those drawbacks. Let’s look at how we modified that classic salting technique. Schema Let’s assume that the original table schema is as follows: CREATE TABLE keyspace1.standard1 ( key blob, value blob, PRIMARY KEY (key) ) For our algorithm, we modify it to: CREATE TABLE keyspace1.standard1 ( key blob, salt int, chunk_id int, chunk blob, total_chunks int, salt_cardinality int PRIMARY KEY ((key, salt), chunk_id) ) Algorithm Write On a write path, we are going to store the used “max_salt” (salt_cardinality) and the total number of chunks (total_chunks) in every row in addition to the rest of the chunk-specific data for simplicity. If you want to optimize the storage to a bitter end, you can store salt_cardinality and total_chunks only in the “metadata row” (see below). def write_key_blob(key, blob, max_salt=100, max_chunk_size=4096): # Split blob into chunks; last chunk may be smaller split_blob_chunks: List[bytes] = split_blob(blob, max_chunk_size) num_chunks = len(split_blob_chunks) salted_partition_chunks = [[]] * min(num_chunks, max_salt) for chunk_id, chunk in enumerate(split_blob_chunks): salted_partition_chunks[chunk_id % max_salt].append( (chunk_id, chunk) ) for salt, chunks in enumerate(salted_partition_chunks): # Inserts salted partition in one or a few UNLOGGED BATCHes insert_async_batch( key=key, salt=salt, chunks=chunks, total_chunks=num_chunks, salt_cardinality=max_salt ) Complexity Memory: O(sizeof(blob)) CPU: O(num_chunks) DB: O(num_salted_partitions), where num_salted_partitions = min(num_chunks, max_salt) Latency Maximum batches concurrency divided by the num_salted_partitions times the single batch latency. If all batches can be sent out in parallel, the whole write is going to take the time it takes to write a single salted partition data. Read On a read path, we are going to start with reading total_chunks and salt_cardinality from the “metadata row” of a specific Key: row with (key=Key, salt=0, chunk_id=0) primary key. If we have stored any data for the Key, this row should exist. Once we have total_chunks and salt_cardinality values, we can calculate primary key values for every chunk of the original blob we stored before, and read them all in parallel. Below you can find a pseudo-code implementing this idea. def read_key_blob(key: bytes): # SELECT (total_chunks, salt_cardinality) FROM keyspace1.standard1 # WHERE key=key AND salt=0 AND chunk_id=0 total_chunks, max_salt = get_num_chunks(key=key) if not total_chunks: return None # No data for this key salted_results_futures = [] for i in range(min(total_chunks, max_salt)): # Full partition read salted_results_futures.append( async_read(device_id=device_id, salt=i) ) # Poll for completions; can also use async callbacks salted_partition_data = [] while salted_results_futures: not_finished = [] for fut in salted_results_futures: if fut.done(): salted_partition_data.append(fut.result()) else: not_finished.append(fut) salted_results_futures = not_finished # Reassemble blob in correct order chunks: List[bytes] = [None] * total_chunks for partition_data in salted_partition_data: for row in partition_data: chunks[row['chunk_id']] = row['chunk'] # Zero-copy binary iterator over the original chunk return itertools.chain.from_iterable(chunks) Complexity Memory: O(sizeof(original blob)) CPU: O(num_chunks) DB: O(num_salted_partitions), where num_salted_partitions = min(num_chunks, max_salt) Solving Different Blobs’ Version Problem As with regular large partition salting, there are some challenges: How to ensure the chunks you read belong to the same version of the blob? How to ensure concurrent writers of different blob versions to the same Key don’t leave the database’s data in an inconsistent state? A rather common approach to solving the first issue is to add a ‘version’ non-key column: Writers must guarantee that every time they write a new version of the blob, they assign the same cluster-unique version identifier to every chunk (in order to ensure that all chunks of that specific version share the same identifier). A reader would always verify that the versions of each chunk (row) he/she reads for a specific Key match. And if they don’t — one needs to retry a read. Solving the second issue on the DB level is not recommended. It would require using atomic transactions like CQL LWT, which would introduce a performance overhead of their own. A better approach is to ensure the atomicity of writes on the application level by ensuring that there is always a single writer to the same (original) Key at any given point in time. One way to implement this is to have writer Agents manage specific Shard Key ranges. Each Agent acts as a consumer for an MPSC queue and is responsible for writing new versions of blobs belonging to its assigned keys. In general, solving these problems is outside the scope of this blog. Benefits Compared to Classic Salting One can choose any blob chunk size (MAX_CHUNK_SIZE) and any salting cardinality (MAX_SALT) for every key without impacting other keys writes or reads. Unnecessary reads of empty partitions in the read path are eliminated at the price of an additional small read of 8 bytes. Examples of Approaches When Choosing MAX_CHUNK_SIZE and MAX_SALT Approach How to configure Pros Cons Fixed maximum chunk size Always use the same MAX_CHUNK_SIZE for all blobs. Choose different MAX_SALT values per key depending on the blob size to control the size and the number of salted partitions. Use it if you want to create a predictable load on the internal memory allocation system. The number or the size of salted partitions may grow large for big blobs. Fixed maximum number of salted partitions per original key Always use the same MAX_SALT for each key. You may choose to pick a different MAX_CHUNK_SIZE to control the number of rows in each salted partition. Same CPU complexity for read and write operations. Some partitions or cells can get big for big blobs. Control the number of single-row/single-shard partitions to be above a particular portion of the total population Choose MAX_SALT to be 1 for blobs below a certain size, e.g. P99 blob sizes in the data population. Control the amount of data loss in case of losing a quorum. If the threshold is chosen to be some big value, it may create huge partitions, which will in turn create bottlenecks on corresponding shards (CPUs). Clarifications About the Last Policy One of the reasons that we want to salt large partitions (in this particular case, we are effectively salting a “large partition that has all the chunks of our original blob”) is to avoid creating a bottleneck on a single shard. By salting, we are distributing its data among many shards. That not only allows reading and writing its smaller parts in parallel, but also distributes the corresponding overhead among multiple shards of the ScyllaDB database. However, this same distribution is going to become our nemesis when we try to estimate the “blast radius” of data consistency loss when we lose a quorum. Let’s do a quick estimation. Assume the following configuration: Cluster: 3 racks (A, B, and C), each rack having 2 nodes A1, A2, B1, B2, C1, C2 correspondingly. Keyspace: NetworkTopologyStrategy with RF=3 in the current DC. Write consistency: LOCAL_QUORUM (this is a common consistency setting that, when paired with a LOCAL_QUORUM read, ensures immediate visibility of all writes) When we write with a LOCAL_QUORUM, we always write to all 3 replicas — however, the write request is reported as a success when 2 out of 3 replicas acknowledge the write. Therefore, when we estimate potential consistency loss, we should always assume the worst case scenario of when every write has only reached 2 out of 3 replicas. Let’s now assume that nodes A1 and B1 are lost, and so is all their data. If blobs are stored as-is (no chunking) as a single key-value row/partition, then this would mean that we lost a guaranteed consistency for about 25% of our data set: A1 has data of ~50% of the population and there is a ~50% probability that keys replicated on A1 are also replicated on B1. To reduce this number, one should provision more nodes per-rack. Number of nodes per rack Possible data loss amount when losing 1 node in each of 2 racks 3 ~11% 4 ~6.25% 5 ~4% … … If blobs are chunked and salted — each with MAX_SALT of at least as the number of nodes in a single rack — then statistically, each node in the cluster is going to have some chunks of each blob. For the above scenario, we would have to assume that we lost consistency of every key: 100% data loss. Total data consistency loss is a critical scenario that database administrators strive to avoid. So, how can this risk be reduced? One option is to use a hybrid salting strategy, as presented above. If all your blobs are large or blob sizes are uniformly distributed, then you may want to chunk them and store each blob’s chunks as a single partition: always use MAX_SALT=1. If your blob size distribution has a high tail (e.g. P99 is 10MB while the average blob size is 300 bytes), then add only 1% to the value in the table above. To do this, you can use MAX_SALT=1 for all blobs below 10MB and use a larger MAX_SALT (e.g. 100) for all blobs that are larger or equal than 10MB. It allows for effective management of the data loss blast radius. It enables the distribution of the largest blobs across multiple shards, fulfilling the primary goal of chunking. Demo Here is a small demonstration of the idea described above. We wanted to show that the latencies of reading and writing of the chunked 60MB blobs is comparable to latencies of 1MB or 64KB small blobs. The small chunk writes and reads steps were running with the fixed concurrency of 15 to make sure we are not hitting any possible bottlenecks. We have implemented a write API that receives blob and salting parameters and stores it in a chunked form as described above. We have also implemented a corresponding read API that reads the blob previously stored by a write API back and returns it as a vector of chunks. We are going to measure the latency of API calls above: For writes: the time all chunks of a given blob are written to the DB. For reads: the time all chunks are read from the DB and the corresponding vector of chunks is returned to a caller. We are going to issue APIs that chunk the blob with concurrency 1 in order to avoid the possibility of queuing and get the clean latency measurements. You can find the API for managing salted blobs within the SaltedBlobStore class in this repository, with implementations available in both Python and C++. The following results were obtained using the C++ API. The benchmark tool has 4 steps: Write a given number of blobs of a given size with one of the write APIs mentioned above. Read the blobs written in step 1 using one of the read APIs mentioned above. Write the same amount of data written in step 1 using single chunk writes of the same size we used for chunking blobs in step 1. Read the data written in step 3 back. Our setup is: ScyllaDB: a single node with 15 shards: i8g.4xlarge AWS VM. Loader: a single c5.12xlarge AWS VM. Compactions are disabled to make steps 1 and 3, and 2 and 4 comparable since they run back-to-back. We write 1000 blobs 60MB each in the demo. In the first iteration, we use 1MB chunks and max_salt=60 since there will be exactly 60 chunks. In the second iteration, we use 64KB chunks and max_salt=100. Then we compare the API-level latencies between these two iterations. Benchmark Results Iteration 1 Total amount of data written/read: Large blobs : 1,000 × 60 MiB = 58.59 GiB total Small blobs : 60,000 × 1024 KiB ≈ 58.59 GiB total Chunk size : 1 MB max_salt=60 small blobs concurrency=15 large blobs batch write/partitions read concurrency = 60 (all partitions are read and written in parallel) Metric Large Write (60MB) Large Read (60MB) Small Write (1MB) Small Read (1MB) Effective Throughput 682.1 MiB/s 758.3 MiB/s 1420.1 MiB/s 1238.1 MiB/s Execution Duration 1m 28s 1m 19s 42.3 s 48.5 s Operation Count 1,000 1,000 60,000 60,000 Latency Metric Large Write (60MB) Large Read (60MB) Small Write (1MB) Small Read (1MB) Minimum Latency 85.7 ms 64.0 ms 2.5 ms 1.2 ms Median (p50) 87.7 ms 74.9 ms 7.3 ms 10.5 ms Tail Latency (p99) 92.5 ms 87.1 ms 38.6 ms 39.4 ms Maximum Latency 98.1 ms 91.2 ms 59.7 ms 80.0 ms Iteration 2 Total amount of data written/read: Large blobs : 1,000 × 60 MiB = 58.59 GiB total Small blobs : 960,000 × 64 KiB ≈ 58.59 GiB total Chunk size : 64 KB max_salt=100 small blobs concurrency=15 large blobs batch write/partitions read concurrency = 100 (all partitions are read and written in parallel) Metric Large Write (60MB) Large Read (60MB) Small Write (64KB) Small Read (64KB) Effective Throughput 998.0 MiB/s 1022.9 MiB/s 1124.5 MiB/s 438.8 MiB/s Execution Duration 1m 0s 58.7 s 53.4 s 2m 17s Operation Count 1,000 1,000 960,000 960,000 Per-Operation Latency Characteristics Latency Metric Large Write (60MB) Large Read (60MB) Small Write (64KB) Small Read (64KB) Minimum Latency 58.8 ms 52.3 ms 0.6 ms 0.6 ms Median (p50) 59.8 ms 57.8 ms 0.8 ms 0.9 ms Tail Latency (p99) 64.2 ms 69.6 ms 1.1 ms 1.2 ms Maximum Latency 91.9 ms 76.0 ms 2.0 ms 23.8 ms These results validate the efficiency of the salting strategy for massive objects. While we were writing with virtually the same throughput as cassandra-stress at the beginning of the article, using 64KB chunking results in about 10s faster average writes for the same 60MB of data and 22x lower P99 write latencies. We see that 1MB chunking results in about 40% worse latency across all percentiles compared to 64KB chunking. This is not very surprising because 1MB chunks are pretty large blobs themselves and trigger the same issues like larger blobs. Overall, these performance metrics are highly favorable compared to the raw 60MB blobs’ write/read latencies we saw with cassandra-stress in the original test we shared. Conclusion: High Performance, Controlled Risk The challenge of storing large blobs in ScyllaDB is fundamentally about managing memory pressure and latency. Our experiments confirmed that a large 60MB blob written as a single key-value row resulted in a write latency of about 567ms/1436ms average/P99 latency. The Modified Salting Technique solves this bottleneck by transparently fragmenting the large blob and allowing its parts to be processed in parallel across multiple shards. This approach successfully reduces write/read latency to highly performant levels, comparable to small key-value operations (60ms/64ms average/P99) with a very low tail latency. Plus, there is a good potential to improve this even further if one increases the write/read concurrency. This technique offers flexibility not found in classic salting: most notably, the ability to configure the salting cardinality (MAX_SALT) on a per-key basis. This flexibility is the key to managing a delicate trade-off: For optimal performance and shard distribution, a large MAX_SALT is preferred. For critical data where minimizing the data loss blast radius during a quorum failure is paramount, a low MAX_SALT (e.g., MAX_SALT=1) can be used to isolate the data to fewer nodes. By implementing a hybrid approach — using low salting for small to medium blobs, and high salting for the largest ones — administrators can achieve high throughput and low latency for their entire data set while retaining control over data loss risk. This modified salting technique can help users squeeze better performance from ScyllaDB when dealing with mixed-size datasets and large object storage. If you’re interested and want to give this chunked blob technique a try, you can find working code samples and the benchmark used above at https://github.com/scylladb/scylla-code-samples/tree/master/chunking-large-cells/.

Riding the Raft to Strong Consistency in ScyllaDB

24 June 2026, 4:51 pm by ScyllaDB

How ScyllaDB is using per-tablet Raft groups to bring strong consistency to data, without sacrificing the parallelism that makes it fast Distributed systems do not give us simple guarantees for free Distributed databases live in a world where failure is normal. Nodes fail. Networks could have partitions. Clocks might be different in each area that you’re working in. Messages can be delayed or never arrive because of the network itself. A request that looks simple from the application side may cross replicas, shards, data centers, coordinators, and recovery paths before the database can safely answer it. Consistency is one of the most important contracts between the database and the application…and it’s hard. When the database says a write succeeded, what exactly does that mean? When a second client reads the same key, what state should it see? When two updates race, who wins, and can the application reason about the result? For many workloads, eventual consistency is the right approach. It gives a distributed database room to stay highly available and fast, even when part of the system is under stress. For now, these workloads are where ScyllaDB shines. But for other workloads, “eventually correct” creates too much ambiguity. Those workloads need a stronger contract. Eventual consistency was the right foundation for ScyllaDB ScyllaDB started as a high-performance, Cassandra-compatible, eventually consistent database. That model is powerful: the system is leaderless, work is distributed across shards, and applications choose consistency levels such as ONE, QUORUM, or ALL (depending on their needs). In this model, a client sends a write to a coordinator, the coordinator forwards it to replicas, and the operation is acknowledged according to the selected consistency level. Reads follow a similar pattern: replicas respond, and the coordinator waits for enough responses to satisfy the requested consistency level. Figure 1: Write and read patterns This design gives applications a flexible tradeoff between latency, availability, and consistency. It remains valuable, especially for high-scale workloads that prioritize availability and throughput. But some parts of a database should not be “eventual” Eventual consistency becomes harder when the data being changed is not naturally commutative, when different observers must agree on one order of events, or when a wrong answer is expensive. Metadata is the clearest example. Schema, topology, tablet placement, and cluster state describe the database’s internal operations. If nodes disagree about this information, the system becomes harder to operate safely. The same pattern appears in application data. Counters, account balances, inventory reservations, entitlement checks, idempotency records, and conditional updates all become simpler when the database can provide a clear, strongly ordered answer. Without that guarantee, application developers often compensate by adding retries, custom conflict resolution, reconciliation jobs, or application-side locks. Figure 2: Gossip-based topology spreads membership information without a single global source of truth, which is powerful for availability but eventually consistent by design. For example, “last-write-wins” sounds simple: keep the newest update. But if two clients update the same value at the same time, one update can disappear. Initial value: {} Client 1 writes: {A} Client 2 writes: {B} Final value: {B} Both writes may have been accepted, but only one survives. The problem is that last-write-wins avoids coordination, but it does not merge intent. For mutable data, this can mean lost updates. To learn more: https://aphyr.com/posts/294-jepsen-cassandra Strong consistency gives the system one accepted order An alternative approach is strong consistency. Instead of allowing independent updates to happen concurrently and converge later, the system establishes one accepted order for operations. In practical terms, this means that once an operation is committed, later operations observe that committed state according to the consistency model. This provides correctness as well as simplicity. Developers can reason about the database as if there is one clear sequence of operations. Operators can reason about topology and schema changes as deterministic state transitions. And the database can remove entire classes of ambiguity because it no longer needs to guess which version of the world is the right one. Strong consistency is an all-around simpler programming model for the parts of the application where correctness, ordering, and predictability matter more than the lowest possible write latency. Why Raft is the right building block Raft provides the foundation for this stronger consistency model. At a high level, a Raft group chooses one node to be the leader. The leader receives the request, records it, and makes sure most of the group has the same record. Only then does the group treat the request as accepted. Figure 3: Raft request access by majority process Because all nodes follow the same ordered list of accepted requests, they all reach the same result in a clear and predictable way. This model is especially useful in a distributed database because it gives the system a clear answer to a hard question: Who is allowed to decide what happens next? In Raft, the leader proposes the order and the majority confirms it. ScyllaDB adopted Raft because some database operations are too important to be left to eventually converging metadata. Schema changes, topology changes, and strongly consistent data operations all need a clear, agreed-upon order. Without that, two nodes may observe changes in different orders, or the system may need complex recovery logic to repair disagreement after the fact. Figure 4: Raft turns a distributed decision into an ordered log: leader election, append, replicate to a majority, commit, and apply. This is also important for elasticity. ScyllaDB’s tablet architecture is designed for flexible data distribution across the cluster, and Raft-managed topology allows operations such as adding nodes and moving data to be coordinated safely. ScyllaDB uses tablets, together with consistent topology updates, as a foundation for faster and more flexible scaling. In other words, ScyllaDB adopted Raft not just because Raft is a well-known consensus algorithm, but because it gives the database a reliable coordination layer. It replaces “every node eventually figures it out” with “the group agrees on the order first, then applies the result.” That is the foundation needed for strong consistency; there’s just one: Agreed order. Committed history. Deterministic path from request to replicated state. At ScyllaDB, the first step in adopting Raft was to use it for topology and metadata changes. This gave those critical operations strong consistency guarantees while also reducing complexity across the system. Figure 5: In ScyllaDB, shard 0 runs Raft for metadata tables while the other shards continue doing user-data and storage-engine work. The next milestone for ScyllaDB: strongly consistent tables Our next step is bringing the same idea to user data through strongly consistent tables. A strongly consistent table is built on top of the Raft log. A write is routed to the Raft leader for the relevant tablet group, appended to that group’s log, replicated to a majority, committed, and applied to the storage engine. Figure 6: High-level strongly consistent write path: route to the tablet group leader, append to the Raft log, replicate to a majority, commit, and apply to storage. This is a major shift in how users can model correctness in ScyllaDB. Instead of treating strong guarantees as a special case workaround, users can choose a consistency model at the data-modeling level. Tables that need the classic high throughput eventual consistency behavior can keep it. Tables that need stronger ordering can use the strong path. It’s important to note: ScyllaDB is not replacing eventual consistency. We are offering multi-consistency. Our users will be able to choose the right consistency model for each workload. And we will deliver strong performance in both cases. Why a Raft Group for each tablet? In ScyllaDB, we already use Raft for important system-level coordination. For example, Raft is used to safely sequence topology and schema metadata changes. That makes cluster operations consistent and reliable. So a natural question is: If we already have Group 0, why not use it as the single synchronization point for all strongly consistent data operations? At first glance, that sounds simpler. We already have one Raft group in the system. We could use it as the “master sync point” for every read, write, and data-related operation. But, unfortunately, it’s not that simple. ScyllaDB clusters can contain many tablets. Tablets are the basic units of data distribution: each tablet owns a portion of a table’s data and can be independently managed and moved across the cluster. To understand the issue, imagine a busy system with many tablets, heavy reads, heavy writes, topology activity, background work, maintenance operations, and user traffic all happening at the same time. If all of these operations had to pass through a single Raft group, that group would become a global synchronization bottleneck. Because Raft is a consensus protocol, operations must be ordered and committed consistently. (That’s what gives us correctness). But if one global group is responsible for ordering everything, then unrelated operations are forced into the same queue. A write to one tablet may have to wait behind work for another tablet. A read or write on one part of the dataset may be delayed by background activity somewhere else in the cluster. All this hurts both latency and throughput. A better option is to “divide and conquer.” Since the tablet is already the natural unit of data ownership, we can also make it the natural unit of synchronization. Instead of forcing all strongly consistent operations through one global Raft group, each tablet gets its own Raft group. This means each tablet handles its own coordination, replication, and bookkeeping. Operations on one tablet do not need to block unrelated operations on another tablet. The system can make progress in parallel, across many independent Raft groups, instead of serializing everything through a single global queue. The result is a much more scalable architecture with: Lower contention: Each Raft group handles only the operations for its own tablet. Better parallelism: Many tablets can process strongly consistent operations at the same time. Improved throughput: The system is no longer limited by one global synchronization point. Lower latency: Unrelated operations do not wait behind each other as often. Better user experience: Strong consistency becomes practical without turning the entire database into a single serialized pipeline. This is the same basic reason ScyllaDB’s tablet architecture exists in the first place: splitting data into smaller independent units allows the system to scale, rebalance, and operate in parallel. Tablets were designed to support faster, more flexible scaling by separating data ownership from fixed server ownership. A single global Raft group is nice because it is easier to reason about. However, ScyllaDB is built for high-throughput, low-latency workloads. A single global queue for all of them would immediately become the bottleneck. By assigning a Raft group to each tablet, we keep the correctness properties of Raft while preserving the parallelism that makes ScyllaDB fast. Each tablet becomes an independent unit of consistency. The cluster as a whole can continue to behave like a distributed, parallel database rather than a single synchronized queue. In short: Group 0 is great for global metadata. Per-tablet Raft groups are what make strong consistency scalable for user data. Raft leaders and followers: one voice for the group Raft is a consensus protocol designed around a simple idea: instead of allowing every replica to independently decide what should happen next, the group elects one replica to act as the leader. The other replicas become followers. This leader-based model makes the system easier to reason about because all changes flow through a single authority for that Raft group. The original Raft paper describes this as one of Raft’s main design choices: decomposing consensus into understandable pieces, especially leader election and log replication. In normal operation, the leader is responsible for accepting new operations, appending them to its log, and replicating those log entries to the followers. A follower does not independently decide the order of operations. Instead, it follows the leader’s log and acknowledges replicated entries. Once an entry is safely replicated to a majority of the group, it can be considered committed and applied to the replicated state machine. This is the core mechanism that allows multiple machines to behave as if they agreed on one ordered history of changes. The important point is that the leader is not “more correct” than the followers. It is simply the replica currently elected to coordinate the group. Followers still store the replicated state, validate the leader’s messages according to the Raft rules, and participate in making progress by acknowledging replicated entries. The leader can only commit entries when it has agreement from a quorum. This is why Raft depends on a majority of replicas being available; without a quorum, the group cannot safely make new decisions. ScyllaDB’s Raft documentation also highlights this quorum requirement for Raft-managed operations. A useful way to think about it is this: The leader proposes the order. The followers confirm and persist that order. The majority makes it durable. Raft leaders also send periodic heartbeat messages to followers. These heartbeats tell the followers that the leader is still alive and still responsible for the current term. As long as followers keep receiving valid communication from the leader, they remain followers. If a follower stops hearing from the leader for long enough, it assumes the leader may have failed and starts an election by becoming a candidate. If that candidate receives votes from a majority, it becomes the new leader. This election mechanism allows the group to recover automatically when the current leader crashes or becomes unreachable. This distinction between leader and follower is especially important in distributed databases. A database cluster is not running on one machine. It is running across many machines, and those machines can fail, restart, disconnect, or see events in different orders. Without a clear coordination model, two replicas could make conflicting decisions at the same time. Raft avoids that by ensuring that, for a given term and Raft group, there is one leader responsible for sequencing new changes. In ScyllaDB, Raft has already been used to make important metadata operations safer and more consistent, including schema and topology changes. ScyllaDB’s work on Raft-managed topology means topology operations are internally sequenced consistently, rather than relying on each node to independently converge on the same result. ScyllaDB also has one place that coordinates topology changes together with the Raft leader. If that leader goes down, another leader can take over and continue from the same shared information, instead of guessing or starting from a different view. For strongly consistent data, the same basic idea applies: the leader of the relevant Raft group is the place where the ordered history of that group is created. A write is not just “sent somewhere and eventually copied.” It is placed into a replicated log, agreed on by a majority, and then applied in the same order by the replicas. Followers are not passive backups in the weak sense; they are active participants in preserving the agreed history. This model gives us a clean mental picture: Without Raft: replicas may need to reconcile different views after the fact. With Raft: replicas agree on the order first, then apply the result. That is the key difference. Raft does not remove the complexity of distributed systems; failures, latency, partitions, and recovery still exist. But it gives the system a disciplined way to handle that complexity. The leader gives each Raft group a single coordination point, the followers provide durable replicated state, and the quorum rule ensures that progress is made only when enough replicas agree. In other words, Raft leader/follower replication is not about creating one “special” node forever. It is about creating a temporary, elected coordinator that gives the group one consistent voice. If that voice disappears, the group elects another one. The result is a system that can keep a strongly ordered history of changes even while individual machines come and go. Leader awareness: sending requests to the right place Now that we’ve seen how every Raft group has a leader, let’s look at the next important question: How does the client know where to send the request? In a Raft-based system, the leader is the replica that coordinates the work for the group. It decides the order of operations, appends new entries to the replicated log, and drives replication to the followers. For ScyllaDB Strong Consistency, where every tablet has its own Raft group, this means that every tablet also has a current Raft leader. That creates an important difference from eventual consistency. With eventual consistency, a client request can usually be sent to one of the replicas, and that replica can act as the coordinator for the operation. The driver does not necessarily need to know which replica is “special,” because there is no Raft leader that must order the operation first. With strong consistency, the situation is different. If a request reaches a follower, that follower cannot independently decide the order of the operation. The leader must coordinate the operation. The follower may have the data, and it may be part of the Raft group, but it is not the replica currently responsible for sequencing new writes or strongly consistent operations. So the request has to reach the leader. Request forwarding To make this work, ScyllaDB implements request forwarding. It works like this: The client sends a request to one of the replicas. If that replica is the Raft leader for the tablet, it handles the request directly. If that replica is a follower, it acts as a proxy for the request. The leader processes the request through Raft. The result is returned back through the forwarding replica to the client. This gives us an important correctness property: Even if the client reaches the wrong replica, the operation is still coordinated by the Raft leader. That is exactly what we want. The leader remains the single place where the ordered history of the tablet is created. Followers can help route the request, but they do not bypass the leader or make independent decisions. This forwarding mechanism is especially useful because leadership can change. A leader may fail, restart, become unreachable, or step down. When that happens, the Raft group elects a new leader. Request forwarding gives the system a way to continue operating even when the client does not yet know about the new leadership state. The cost of forwarding However, request forwarding has a cost. If the client sends the request to a follower, the request has to make an extra network hop: client → follower → leader → follower → client Instead of the simpler path: client → leader → client That extra communication adds latency. It also increases the number of messages inside the cluster. For occasional requests, this may be acceptable. But for a high-performance database, especially under heavy read and write workloads, unnecessary network hops matter. This is where leader awareness becomes important. Leader-aware drivers A leader-aware driver allows the client driver itself to learn which replica is the leader for a given tablet. Instead of blindly sending requests to any replica and relying on forwarding, the driver can send future requests directly to the leader. The first request may still go to any replica. If it reaches a follower, the follower can forward it to the leader. But when the response comes back, the driver can also learn: “For this tablet, this replica is currently the leader.” From that point on, the driver can route requests directly to the leader. So the flow becomes: The driver sends an initial request. If needed, ScyllaDB forwards the request to the current leader. The response includes updated leader information. The driver remembers the leader for that tablet. Future requests go directly to the leader. This keeps the correctness benefit of forwarding, while reducing its performance cost. Forwarding is still needed Leader-aware drivers do not remove the need for request forwarding completely. Leadership is not permanent. A Raft leader can change at any time due to failures, restarts, topology changes, or elections. When that happens, the driver may temporarily have stale information. In that case, forwarding is still the safety net: If the driver sends a request to the old leader or to a follower, ScyllaDB can forward the request to the new leader and update the driver again. So forwarding remains important, but it becomes the exception rather than the normal path. Instead of paying the forwarding cost on every request, we mainly pay it at the beginning of communication, after the leader has changed, or when the driver’s leader information is stale. That is a much better model for performance. Balancing correctness and performance Leader awareness gives us the best of both worlds. Request forwarding gives us correctness and simplicity: requests always reach the Raft leader, even if the client does not know who the leader is. Leader-aware drivers give us performance: once the driver learns the leader, it can avoid unnecessary hops and send requests directly to the right replica. For strongly consistent workloads, this is a major optimization. Strong consistency already requires coordination, replication, and quorum agreement. We do not want to add avoidable network hops on top of that. By making the driver aware of tablet leadership, ScyllaDB can preserve the Raft correctness model while reducing latency and improving throughput. In short: Request forwarding makes strong consistency work. Leader-aware drivers make it fast. The leader-aware driver is planned for the 2026.3 release. In 2026.2 we release forwarding. The strongly consistent read path: reading from the leader and using a barrier After understanding that every Raft group has a leader, and that writes must be coordinated by that leader, the next natural question is: What about reads? At first glance, reads may look simpler than writes. A read does not change the data, so it may seem safe to read from any replica. But with strong consistency, this is not always enough. The problem is that replicas may not all be at exactly the same point in the Raft log at the same time. A follower can be slightly behind the leader. It may still be catching up on committed entries. If we read from that follower without any additional coordination, we may accidentally read an older version of the data. For eventual consistency, this may be acceptable depending on the chosen consistency level and workload. For strong consistency, we need a stronger guarantee: A read must observe the latest state that was safely committed before the read. That means the read path also needs to respect the Raft ordering model. Reading from the leader The simplest way to make a strongly consistent read is to send the read to the Raft leader. The leader is the replica that coordinates the Raft group. It receives operations, orders them, replicates them, and knows the current progress of the group. Because the leader is the place where the group’s ordered history is created, reading through the leader gives us a natural consistency point. The basic read path looks like this: The client sends a read request. The request is routed to the Raft leader for the tablet. The leader makes sure it is still allowed to act as leader. The leader reads from the state that reflects the committed Raft log. The result is returned to the client. This keeps the read aligned with the same ordering model used by writes. In other words: Writes go through the leader to enter the log. Reads go through the leader to observe the committed result of that log. This gives the system a clean and understandable consistency model. The leader is not only the place where changes are ordered; it is also the safest place to observe the latest committed state. Why reading from a follower is not always enough A follower is still a valid replica. It participates in the Raft group, stores the replicated log, and applies committed entries. But a follower can temporarily lag behind the leader. For example: A write is committed by the leader and a majority of replicas. One follower has not applied for that committed entry yet. A client reads from that follower. The client may see the old value. From the point of view of that follower, nothing “wrong” happened. It simply has not caught up yet. But from the point of view of strong consistency, the reading may be stale. This is why strongly consistent reads cannot blindly read from any replica without additional coordination. If we want reads to be strongly consistent, the system must prove that the replica serving the read is up to date enough for that read. What is implemented today Today, before serving a strongly consistent read, ScyllaDB runs read_barrier(). This currently requires network communication with a quorum and also waits for the Raft state machine on the leader to apply any previously written commitlog entries to memtables. In other words, the read must first make sure the leader has caught up with all committed changes before returning a result. In the near future, we plan to implement Raft leases, which will allow the leader to serve reads locally without additional network hops. Because of this, we expect strong consistency performance to eventually be on par with eventual consistency, and in some read-heavy cases, it may even be better. How the leader keeps followers updated The Raft leader is also responsible for keeping the followers up to date. When a new operation is accepted by the leader, the leader appends it to its local Raft log and then sends it to the followers. The followers append the same entry to their own logs and acknowledge it back to the leader. Once the leader receives acknowledgments from a majority of replicas, the entry is considered committed. After that, the committed entry can be applied to the actual database state. The flow looks like this: Client request Raft leader appends entry to its log Leader sends the entry to followers Followers append the entry and acknowledge Majority confirms Entry is committed Replicas apply the committed change The leader has two jobs: It orders new operations. It continuously brings followers to the same ordered state. This is important for reads as well. A follower may temporarily be behind the leader, even if it is healthy. That is why strongly consistent reads usually go through the leader, or require an additional synchronization step such as a barrier before the system can safely answer from a known up-to-date state. How this impacts application developers Strongly consistent tables simplify application logic. Most developers building a payment flow, quota system, inventory reservation, account state machine, or idempotency layer don’t want to reason about replica divergence. They just want the database to protect the invariant. Strong consistency also improves predictability. Predictability is not only about latency. It is about knowing what the system will do when two clients race, when a node restarts, or when an operation is retried. A deterministic ordering layer makes these cases easier to explain, test, and debug. Users should also find that strong consistency makes LWT and transaction workflows much better, cleaner, and faster. Figure 7: Application-level benefits: fewer eventual consistency anomalies, better counters, better predictability, simpler logic, and a path to better LWT behavior. How to use strongly consistent tables This feature is still experimental so please use it with caution. Strong consistency is selected at the keyspace level. With the strongly-consistent-tables experimental feature enabled, create a tablets-based keyspace with consistency = 'global'. Tables created in that keyspace use the strongly consistent path automatically, so applications continue to use ordinary CQL reads and writes. There is no separate per-statement switch for “strong consistency” in the query itself. CREATE KEYSPACE sc_demo WITH replication = {'class': 'NetworkTopologyStrategy', 'replication_factor': 3} AND tablets = {'enabled': true} AND consistency = 'global'; CREATE TABLE sc_demo.orders ( id int PRIMARY KEY, status text, amount int ); INSERT INTO sc_demo.orders (id, status, amount) VALUES (1, 'paid', 100); SELECT * FROM sc_demo.orders WHERE id = 1; This keeps the usage model simple: choose strong consistency when creating the keyspace, then use ordinary CQL on the tables inside it. A fundamental difference from eventual consistency is that strongly consistent writes do not support user-provided timestamps, so applications must let ScyllaDB assign them automatically. More about LWT Lightweight transactions are one of the places where users already ask the database for stronger semantics. In eventually consistent architectures, LWT is commonly implemented through Paxos, which requires multiple phases such as prepare, accept, and commit. That can add latency and complexity. A Raft-backed architecture gives ScyllaDB a path toward a more unified model: LWT-style behavior on top of a shared replicated log. This should give you fewer duplicated mechanisms, fewer voting rounds, and a simpler execution path. The long-term direction is not “add another special protocol,” but “converge on one ordering and replication layer where it makes sense.” Figure 8: LWT can move from a separate Paxos-based path toward a Raft-backed path with fewer voting rounds and a shared replication layer. Performance Strong consistency is not free. A Raft-based write requires a majority, and write latency can increase compared with the fastest eventually consistent path. That is the nature of asking the system to commit to one order before acknowledging the operation. But the right comparison is not only per-write latency. Strong consistency can also remove repair overhead, conflict-resolution ambiguity, reconciliation logic, and application-side complexity. For correctness-sensitive workloads, paying a predictable coordination cost inside the database can be far better than paying an unpredictable correctness cost across the entire application stack. Figure 9: Architecture convergence: Raft becomes the unified ordering layer for topology, strongly consistent tables, and LWT. We don’t expect our users to make every table strongly consistent; this won’t be the default. Our goal is to give you a choice so you don’t have to choose between a high-performance database and a stronger correctness model. What’s available now and what’s next The backbone implementation for strongly consistent tables is in ScyllaDB 2026.2. Users can create a keyspace configured for strong consistency, create strongly consistent tables, and read and write to them. This is the foundation: the core path proving that ScyllaDB can execute user-data operations through a Raft-backed strong-consistency model. But there’s still more to do. We’re still working on details like tablet migration, tablet split and merge support, recovery behavior, and leader-aware driver support. We’re expecting to release these features in 2026.3. That makes 2026.2 an important milestone: not the end of the journey, but the point where the architecture becomes visible and usable. ScyllaDB is evolving from a high-performance eventually consistent database into a high-performance multi-consistency distributed database. Conclusion: strong consistency is about removing ambiguity Distributed systems are already hard enough. The database should remove ambiguity where ambiguity is dangerous. With Raft-backed strong consistency, ScyllaDB gives users a clearer model for workloads that need correctness, ordering, and predictability. Eventual consistency remains the right choice for many high-scale workloads. Strong consistency becomes the right choice when the application needs one answer, one order, and one source of truth. We’re excited to share this with you and look forward to your feedback!

The Evolution of Cassandra Data Movement at Netflix

19 June 2026, 11:53 pm by Netflix TechBlog - Medium

By Guil Pires, Jennifer Prince, Jose Camacho, Ken Kurzweil, Phanindra Chunduru

Background

In a previous post, we introduced Data Bridge, a unified management plane for batch Data Movement at Netflix. Historically, several bespoke Data Movement connectors were developed across different engineering organizations to fulfill their specific requirements. Over the last few years, the Data Movement team has started centralizing these offerings through an abstraction that provides a catalog of connectors, along with simple UI and APIs to initiate Data Movement jobs.

One such case is the Cassandra to Iceberg connector. Apache Cassandra powers mission critical applications at Netflix, including Member, Billing, Recommendations, Subscriptions and many more. These use cases heavily leverage Data Movement to Apache Iceberg for many analytics and operational tasks, and central to this movement was a connector for Cassandra to Iceberg built in-house named Casspactor. As many Cassandra based Data Abstractions emerged, such as Key Value, Time Series and Graph — the need for larger and more complex Data Movement with transformations became more critical to the business.

Data movements are fundamentally fulfilled by leveraging the existing Cassandra backup infrastructure. Regularly scheduled backups are performed directly on the Apache Cassandra nodes, via a sidecar process managing the upload of all necessary SSTables and associated Metadata files directly into Amazon S3. When a Data Movement job is initiated, the job constructs the specific backup structure it needs by referencing the S3 based metadata, allowing it to precisely locate the SSTable files. The engine then downloads these files, performs the required mutation compaction and processing, and finally writes the fully transformed, compacted data directly into the target Apache Iceberg tables.

Image 1: Cassandra Cluster Backups to S3

Casspactor: The Engine We Outgrew

Casspactor processed roughly 1,200 data movements per day, transferring approximately 3 PB of data from Apache Cassandra into Apache Iceberg tables. It served some of the most critical workloads at Netflix. For years, it worked. Then, two compounding challenges made it clear we needed a fundamentally different architecture.

Fragile Metadata Dependencies

Before Casspactor could move a single record, it needed to answer a deceptively simple question: which backup exists, is it complete, and what does it contain?

Casspactor assembled this answer from multiple independent systems:

Image 2: Casspactor’s Composite View of a Backup

Each system had its own failure modes, update cadences, and accuracy guarantees. Casspactor’s view of the world was a composite, and composites diverge from reality.

Metadata fell out of sync with actual backups, causing Casspactor to read stale or incorrect data silently. Routine maintenance on the Cassandra Clusters triggered uncoordinated snapshots, and because Casspactor required all nodes in a region to snapshot at the same clock second, a single node replacement could break data movement for an entire region.

The fix was hiding in plain sight. The answer to “which backup exists and is it complete?” already lived in the backup storage layer (Amazon S3) itself. By reading metadata directly from the backup files, we could replace the entire dependency chain with a single source of truth.

Every Connector Inherited Casspactor’s Limitations

Cassandra at Netflix does not just store raw tables. It backs higher level data abstractions, such as Key Value, Time Series, and others, each with its own data model, access patterns, and semantics. When any of these abstractions needed to move data to Iceberg, they all funneled through Casspactor.

Every abstraction inherited Casspactor’s constraints:

  • Skewed partition failures: Casspactor could not handle tables with large partitions, a common pattern in Key Value and Time Series workloads. Jobs crashed with out-of-memory errors on some of Netflix’s largest datasets.
  • No data model awareness: Casspactor moved raw Cassandra tables as is. Connectors for Key Value and other abstractions had to bolt on post processing to reconstruct their data models from the raw output — extra cost, extra complexity, and an extra surface for failures.
  • Intermediate table bloat: Casspactor wrote to an intermediate Iceberg table before producing the final output. The Key Value connector added another intermediate table and a snapshots table. Connectors for abstractions on top of Key Value added even more. This compounded into significant storage cost overhead.
  • Inability to Time Travel: by relying on multiple services to compose a backup unit, Casspactor was unable to restore prior backups in the event of cluster Topology or Keyspace schema changes.
  • Monolithic design: Casspactor was built as a single connector, not as an engine. There was no way to build a family of purpose built connectors on a shared foundation.

We needed something fundamentally different: an engine that reads directly from backups in S3, produces standard Spark DataFrames, and lets each data abstraction build its own connector with full awareness of its data model. One foundation, many connectors.

The New Stack: A Layered Architecture

The new architecture, built upon the foundation of Apache Cassandra Analytics and the in-house Move Data framework, represents a fundamental shift toward a layered, purpose-built stack designed for reuse and maintainability. This new engine was conceived with clear separation of concerns, moving away from Casspactor’s monolithic design. The architecture is intentionally layered with the foundation being a core S3 reading capability: the Cassandra Analytics Wrapper, which is built on top of the Open Source Cassandra Analytics with Netflix’s internal backup representation and an S3 Client.

This layer handles the raw data retrieval from backups, translating it into standard Spark DataFrames. Sitting atop this foundation is a “Connector Factory” model, via both Java UDFs and transforms which allows individual data abstractions (Key Value, Time Series, others) to build highly optimized, data model aware connectors that process the generic Spark DataFrames, avoiding the need for complex, expensive, and failure-prone post-processing steps. This layered approach ensures that improvements to the core reading engine benefit all connectors, while the connectors themselves are focused solely on data transformation.

Image 3: The new Connector layered stack
  • Handles Skewed Partitions: By moving the mutation compaction and processing to the Executor level within Spark, the new engine can efficiently handle tables with highly skewed or wide partitions, a major pain point for Casspactor. Crucially, this processing occurs without excessive data shuffling, preventing out-of-memory errors and enabling reliable movement of Netflix’s largest datasets.
  • Operates at Spark DataFrames (No Intermediary Tables): The new architecture directly generates standard Spark DataFrames from the Cassandra backups. This eliminates the need for Casspactor’s costly, multi-stage intermediate Iceberg tables, which led to storage bloat and operational complexity. This native DataFrame operation enables the “Connector Factory” by providing a universal, easily consumable interface for building diverse, model specific connectors.
  • Jobs Auto Size: The engine integrates intelligent auto-sizing capabilities, allowing jobs to dynamically adjust resource consumption based on the source table’s characteristics. This removes the burden of manual tuning from engineering teams, ensuring optimal performance and cost efficiency without sacrificing reliability.
  • Reduced Dependencies: By reading metadata directly from the backup files stored in S3, the new stack removes the fragile, multi-service dependency chain that plagued Casspactor. S3 becomes the single, authoritative source of truth for backup existence and completeness, vastly improving data movement reliability and consistency.
  • Time Travel: A critical feature of the new stack is the ability to process the schema, cluster topology, and data as a cohesive unit at a specific point in time. This capability provides robust time travel functionality, essential for auditing, debugging, disaster recovery and reproducing past data states.
  • Performance: Collectively, these architectural improvements, including native DataFrame processing, optimized partition handling, and streamlined metadata retrieval have resulted in notable performance gains, reducing overall data movement execution runtime and cost compared to the legacy Casspactor system.
  • Cost: by eliminating intermediary Iceberg tables and efficient SSTable compaction on Executors, the new stack needs a significantly smaller storage and compute footprint leading to significant cost savings in the order of USD millions.

The Journey Towards a Safe Migration

The successful validation of the new stack was the critical first step, but it only marked the beginning of the most challenging phase: the migration. Large scale data migrations are inherently complex, high-risk undertakings that can be time consuming and often result in customer frustration and service disruption. To navigate the high stakes of decommissioning a mission-critical system like Casspactor and seamlessly replacing it, we needed a strategy that prioritized reliability and transparency above all else.

The migration was fundamentally enabled by a Like-for-Like strategy, which served as the cornerstone of our Platform Engineering philosophy, abstracting complexity. The core tenet was to maintain absolute consistency across the user-facing interface, the output contract, and the final data artifact. This meant ensuring that the data movement parameters defined via the Data Bridge abstraction remained unchanged, and, critically, the schema, metadata, and data within the destination Iceberg tables were identical to the legacy output. By preserving these external contracts, we eliminated the need for complex, time-consuming coordination with dozens of internal teams who relied on these data pipelines. This approach transformed the migration from a distributed, high-risk, multi-team effort into an internal platform implementation detail, allowing us to achieve a transparent, zero-impact transition and accelerate the retirement of the legacy system without requiring any code changes or validation from downstream users.

To navigate this migration, we developed a strategy anchored by three core pillars that serve as a blueprint for successful, large-scale data migrations:

  1. Validation: Establishing and maintaining absolute confidence in data consistency through rigorous, ongoing validation.
  2. Visibility: Instrumenting every part of the system to provide a clear, real-time understanding of migration progress and system health.
  3. Safety: Ensuring user impact is minimized or eliminated, despite the inevitable system failures, by leveraging abstractions and robust fallbacks.

The next section will provide a detailed exploration of these key pillars.

Pillar 1: Validation

Trust is earned, and in data migration, it is earned one row at a time. The first pillar is the most critical: providing a measurable guarantee to users and partners that the data produced by the new system is an exact, row-by-row replica of the data produced by the old one.

Our foundational tactic was deploying the new Move Data connector in a “shadow” testing that ran in parallel with the production Casspactor jobs. This allowed us to validate the new system with real-world, production workloads without any customer impact.

Image 4: Shadow job structure leveraged for data validation
  • Let C be the set of rows in the legacy Casspactor output (Iceberg table).
  • Let M be the set of rows in the new Move Data output (Iceberg table).

The test for trust: prove that C = M. This required continuously checking for two conditions:

  1. Rows in C but not in M (C-M): The new system missed data.
  2. Rows in M but not in C (M-C): The new system introduced phantom or erroneous data.

Any result where the cardinality of these difference sets (the number of differing rows) was greater than zero triggered an immediate, high-priority investigation. The target was 100% similarity.

Uncovering and Resolving Disparities

The shadow mode quickly became a powerful forensic tool, exposing “unknown unknowns”, subtle discrepancies that were not bugs in the new system but rather differences in behavior between the new and old systems. Resolving these was the core work of building trust. For each problem we initiated an investigation log where we captured the details, logs, queries that allowed us to diagnose. Based on the assessment the issues were categorized so that similar differences on other datasets were later resolved affecting many of the shadow pipelines.

Maintaining an investigation log was critical to organize the outstanding issues and effectively communicate to stakeholders the progress and confidence of the new connector so that we effectively measure the appropriate level of “confidence” to initiate the migration.

We observed differences in how connectors leverage reference timestamps for Time-to-Live, Consistency Levels, backup selection, and various internal business logic. This continuous, data-driven cycle of discovery and resolution was the mechanism by which we built confidence in the new architecture.

Pillar 2: Visibility

Trust is built in the background, but an active migration requires real-time insight: Visibility. The second pillar involves instrumenting the system to provide an unambiguous, clear understanding of operational health and migration progress.

We extended our instrumentation to the overall migration workflow and its dependencies:

  • Dashboards: We created centralized dashboards to track migration status, visualizing the total number of data movements migrated versus those remaining. The dashboards tracked execution status, average runtime, and cost comparisons between the two connectors.
  • Dependency Tracking: Since the new system relied on a new set of APIs to fetch backup metadata, we implemented detailed metrics for failures to keep track of the APIs or dependencies failed.
  • Alerting: Proactive alerts were set up for job failures (Move Data or Casspactor), failures on Move Data that triggered a fallback to Casspactor or any data discrepancy being detected.

This comprehensive instrumentation allowed the team to be proactive, fix issues as they emerged during the migration, and gain the necessary confidence to accelerate the migration timeline.

Pillar 3: Safety

Even with perfect data correctness and enhanced visibility, the third pillar, Safety is required for a zero-impact migration. The challenge is ensuring that when a system inevitably fails, the user experience is uninterrupted. Our strategy centered on decoupling the user’s workflow from the underlying connector implementation.

Leveraging Abstraction: The Decider Pattern

To achieve a transparent swap, we leveraged the Maestro workflow orchestration platform to implement the Decider pattern:

  1. Data Movement Abstraction: From a user’s perspective, their Data Movement job definition remained the same.
  2. The Decider Step: Internally the workflow responsible to execute the job was modified to include a Decider step. This step took the data movement parameters (source cluster, table name, destination) and invoked a control plane: Connector Controller.
  3. Connector Controller as the Registry: The control plane served as the dynamic registry. Based on the migration cohort and the data movement attributes, it determined and reported the appropriate connector to use either Casspactor (legacy) or Move Data (new).

This abstraction gave our team complete control. We could upgrade or rollback any connector for any data movement instantly by simply updating a configuration in the controller, with zero modification required to the thousands of downstream customer workflows. Crucially, this abstraction guaranteed the critical safety net: a conditional step in the Maestro workflow logic ensured that if the Move Data step fails, it would immediately execute the Casspactor step.

This pattern would increase the chances that the user’s data movement completes successfully, even if the new connector encountered a bug or transient failure during the initial rollout phases. User impact was completely eliminated; they might see a slightly longer runtime in the event of a failure and fallback, but they would never see a migration failure or suffer from stale data.

Image 5: The Decider Pattern Implementation via Maestro

Beyond the workflow, the new system architecture itself was inherently more resilient. By building the new data movement connector on Cassandra Analytics and reading backups directly from S3, we removed fragile dependencies on deprecated internal services.

Conclusion

The migration from Casspactor to the new, layered architecture built on Cassandra Analytics and the Move Data connector was more than a typical “tech debt” project; it was a fundamental shift in our approach to data movement reliability and scalability at Netflix.

The legacy system, while serving us well for years, was ultimately constrained by monolithic design, fragile metadata dependencies, and an inability to handle the complexity of modern data abstractions. The new stack resolves these issues by delivering a robust, cost-efficient, and inherently more resilient solution that reads directly from S3, handles wide partitions gracefully, and eliminates costly intermediate tables.

Our blueprint for the migration, anchored by the three pillars of Validation, Visibility, and Safety, ensured a transparent and high-confidence transition. Through rigorous shadow testing and a data-driven audit framework, we achieved the desired data consistency. Enhanced dashboards and alerting provided the real-time operational insight necessary to manage risk. Most critically, the implementation of the Decider pattern within our workflow abstraction minimized the impact for all downstream users.

This successful migration validates a core philosophy: by abstracting complexity at the platform level, we can perform large system migrations without burdening our product engineering partners. The new foundation is now ready to support the next generation of Netflix’s data abstractions.

Looking ahead

This foundational work on the Cassandra Data Movement stack has done more than just replace a legacy system: it has become an accelerator for innovation across the entire Data Movement organization. By providing a reliable, performant engine that standardizes data retrieval into Spark DataFrames, we’ve enabled the rapid development of new, highly optimized connectors. This new “Connector Factory” approach has already delivered a dedicated Key-Value to Iceberg and Time Series connectors, both of which are fully aware of their respective data models, eliminating costly post-processing. This architecture is also paving the way for ambitious new initiatives, including the development of a solution for bulk loading data into Cassandra itself, effectively completing the data movement cycle, and enabling safer fleetwide connector rollout with canaries inspired by the Decider Pattern.

We are incredibly grateful for the extensive collaboration among the Data Movement, Data Bridge, Online Data Stores, Membership, Billing, Subscriber and Ads platform teams at Netflix; this work simply couldn’t have been accomplished without their partnership!

The Evolution of Cassandra Data Movement at Netflix was originally published in Netflix TechBlog on Medium, where people are continuing the conversation by highlighting and responding to this story.

Instaclustr product update: June 2026

18 June 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 AI Search for OpenSearch is now generally available on the NetApp Instaclustr Managed Platform

AI Search for OpenSearch is generally available on the NetApp Instaclustr Managed Platform. It brings semantic search, hybrid search, and retrieval-augmented generation (RAG) without the complexity of managing software, infrastructure, or operational management. General availability expands on the public preview, adding support for external LLM and embedding services such as Amazon Bedrock and OpenAI for enterprise search, e-commerce, support chatbots, and observability-style use cases. Unlock new possibilities with AI search—learn more.

Introducing Kafka Client Telemetry: Centralized client metrics for Instaclustr Managed Apache Kafka®

NetApp is introducing Client Telemetry for Instaclustr for Apache Kafka®, designed to deliver broker-integrated visibility into Kafka client and application-level metrics, with telemetry export and centralized collection. Instaclustr for Apache Kafka users can gain visibility into client behavior such as connection status, request rates, error rates, and latency from the broker, simplifying monitoring and supporting a holistic view of client interactions. Compliant Kafka clients collect metrics and push them to the brokers; brokers use an OpenTelemetry Collector to forward metrics to a customer-specified destination, with Prometheus 3.0+ and Datadog supported in this initial release.

Powering low-latency analytics with ClickHouse® and Amazon FSx

Instaclustr Managed ClickHouse integrated with Amazon FSx for NetApp ONTAP is built to run analytical queries directly on file-based data that can transparently tier to lower-cost capacity, without relying on extra staging layers, ingestion pipelines, or format-specific copies to make data queryable. The integration now supports deployments where compute and storage can reside in different VPCs or AWS accounts, enabling flexible, enterprise-grade architectures with consistent storage access across network and account boundaries.

Other significant changes Apache Cassandra®
  • Self-service iccassandra password reset — customers can now reset their iccassandra database password directly from the console via the Connection Info page, eliminating the need to raise a support ticket. The new password is displayed for 5 days before being automatically removed.
  • Released Apache Cassandra v4.1.10 into General Availability on the NetApp Instaclustr Managed Platform, delivering a stability-focused patch release, while deprecating Apache Cassandra 4.1.9.
Apache Kafka® ClickHouse® OpenSearch®
  • New c7g.8xlarge node size on the AWS provider has been added to support OpenSearch clusters.
  • OpenSearch 3.5.0 released to General Availability.
  • AI Search is now available on the free trial.
PostgreSQL® Instaclustr Managed Platform
  • The new AWS region, ap-southeast-6 (New Zealand), has been added.
  • Cluster tag management improvements — multiple enhancements to tag search, display, and validation in the console and API, including prevention of duplicate tag keys for better data consistency.
Future releases OpenSearch®
  • We’re preparing to introduce GPU nodes for OpenSearch on the NetApp Instaclustr Managed Platform, bringing dedicated machine learning capabilities directly into your managed clusters. With GPU nodes, vector indexing can be up to 10x faster and CPU load is reduced, freeing cluster capacity for mission-critical workloads. Additionally, GPUs offer superior cost-efficiency compared to traditional CPU-based vector indexing, driving down the total cost of ownership.
PostgreSQL®
  • We’re close to launching PostgreSQL® integrated with FSx for NetApp ONTAP (FSxN) into GA, now including NVMe support—designed to deliver improved throughput, up to 20% observed greater throughput than we achieved with our public preview. This enhancement combines enterprise-grade PostgreSQL with FSxN’s scalable, cost-efficient storage for better cost, performance, and flexibility, while enabling ONTAP snapshots for backups, mirroring, and multi-region recovery—fast snapshot/restore and daily backups for large databases.
MCP Gateway Service
  • NetApp Instaclustr plans to release the Remote MCP Gateway Service powered by AgentGateway on the Instaclustr Managed Platform. This service will let you, in minutes, provision and configure a production-ready Model Context Protocol gateway to provide LLM access to databases, application data infrastructure services, and REST APIs.
Instaclustr Managed Platform
  • Coming soon, NetApp Instaclustr will be launching the Self-Service Bring Your Own Cloud (BYOC) feature for AWS, offering a fully guided onboarding experience that allows customers to connect their AWS accounts and begin deploying managed clusters directly from the console — making it faster and easier for customers who prefer to run clusters in their own cloud environments.
    Cluster DNS will soon be available for Apache Cassandra and Apache Kafka clusters on AWS allowing you to connect to your applications using simple, stable hostnames instead of long lists of IP addresses. When node IPs change due to scaling, replacement, or maintenance there is no longer a need to update client configuration.
Did you know?

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

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

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

Automate ScyllaDB X Cloud Clusters with Terraform

16 June 2026, 12:27 pm by ScyllaDB

The ScyllaDB Cloud Terraform provider gives you infrastructure-as-code control over your clusters The ScyllaDB Cloud Terraform provider now supports ScyllaDB X Cloud. That means you can provision and manage elastic, autoscaling ScyllaDB clusters the same way you manage the rest of your infrastructure. The ScyllaDB Cloud Terraform Provider The provider lives at registry.terraform.io/scylladb/scylladbcloud. You need a ScyllaDB Cloud account and an API token from cloud.scylladb.com. terraform { required_providers { scylladbcloud = { source = "registry.terraform.io/scylladb/scylladbcloud" version = "~> 0.3" } } required_version = ">= 0.13" } provider "scylladbcloud" { token = var.scylladb_token } Pass the token through a variable. What Is ScyllaDB X Cloud? ScyllaDB X Cloud is ScyllaDB’s elastic cluster tier built on a tablets-based architecture. Traditional ScyllaDB clusters use token ranges pinned to nodes. Scaling them up or down means rebalancing large chunks of data. X Cloud uses tablets, which are smaller, independently moveable units of data. When you add or remove nodes, tablets rebalance in parallel across the cluster, which makes scaling fast and non-disruptive. In practice this means you can: Scale from 100K to 2M ops/sec in minutes, not hours Push storage utilization up to 90% before scaling out (no wasted headroom) Scale-in when load drops (pay for what you use) X Cloud also differs from standard clusters in how you configure it in Terraform: instead of choosing a fixed node type and count, you define a scaling policy and let the platform decide the right size. Provisioning an X Cloud Cluster Here is a complete cluster resource: resource "scylladbcloud_cluster" "xcloud" { name = "my-xcloud-cluster" cloud = "AWS" region = "us-east-1" cidr_block = "172.31.0.0/16" scaling { instance_families = ["i8g"] storage_policy { min_gb = 500 target_utilization = 0.75 } vcpu_policy { min = 6 } } } The scaling block is what makes this an X Cloud cluster. It is mutually exclusive with the node_type and min_nodes fields used by standard clusters (you use one or the other). Key Scaling Parameters instance_families instance_families = ["i8g"] X Cloud scales within a single instance family. The platform picks specific instance sizes within that family as load changes. Sticking with instance_families rather than listing explicit instance_types gives the autoscaler more room to work with. If you do restrict it to specific types, allow at least three different types to give the scaler meaningful options. storage_policy.min_gb storage_policy { min_gb = 500 } The cluster will not scale below this physical storage threshold. Set it when you know your dataset has a minimum size and want to avoid scale-in churn. storage_policy.target_utilization storage_policy { target_utilization = 0.75 } This is the utilization level the autoscaler aims to maintain. The valid range is 0.7–0.9 (default: 0.8). The scaler adds capacity when utilization exceeds target by more than 5%, and removes capacity when it falls more than 5% below target. For write-heavy workloads, staying below 0.85 is a good baseline. It gives compaction and repairs room to breathe. vcpu_policy.min vcpu_policy { min = 6 } The cluster will not scale below this vCPU count, regardless of load. That’s good for latency-sensitive workloads where you want compute headroom even at low traffic. Standard Clusters (For Comparison) If you need a fixed-size cluster or require multi-DC deployments (which will be supported soon), use the standard configuration: resource "scylladbcloud_cluster" "standard" { name = "my-standard-cluster" cloud = "AWS" region = "us-east-1" node_type = "i3.large" min_nodes = 3 cidr_block = "172.31.0.0/16" } Standard clusters use node_type and min_nodes instead of a scaling block. Outputs After apply, the provider exposes: output "cluster_id" { value = scylladbcloud_cluster.xcloud.cluster_id } output "datacenter" { value = scylladbcloud_cluster.xcloud.datacenter } output "node_dns_names" { value = scylladbcloud_cluster.xcloud.node_dns_names } node_dns_names provides the hostnames to pass to your driver configuration. Wrapping Up The ScyllaDB Cloud Terraform provider gives you infrastructure-as-code control over your clusters. For X Cloud specifically, the scaling block replaces the manual node sizing decisions. You just define the baselines and the platform handles the rest. ScyllaDB’s tablets-based architecture means scale events are fast enough to respond “just-in-time” to real traffic changes – so you don’t need to overprovision for peak capacity just in case. For more details, see the full provider documentation at registry.terraform.io/providers/scylladb/scylladbcloud.

ScyllaDB Customer Experience Spotlight: Faisal Saeed

11 June 2026, 12:01 pm by ScyllaDB

Welcome to the second installment of a new blog series introducing some of the experts you might encounter when you work with ScyllaDB. (In the first, we met Tyler Denton, Solutions Architect). Today we’re featuring Faisal Saeed, Principal Customer Engineer on the Customer Experience team here at ScyllaDB. He lives in Singapore and has been at ScyllaDB for more than 2 years. Let’s learn a little about Faisal… What do you do here at ScyllaDB I have a hybrid role where I work with existing customers as their Principal Customer Engineer, helping them ensure their ScyllaDB Cloud / on-prem clusters are in good health and performing according to their expectations. Secondly, I work as a pre-sales Solutions Architect for clients who are not existing ScyllaDB customers and are evaluating ScyllaDB. Here, I often help with data modeling or planning their data migration from their existing database into ScyllaDB Enterprise / ScyllaDB Cloud clusters. Please share a little about your path to ScyllaDB I have worked in the IT industry for about 30 years and have extensive database experience. Before joining ScyllaDB, I was a Principal Solutions Architect with MariaDB for 6 years. Before that, I worked with ACI Worldwide as a database architect on projects for DBS Bank in Singapore. Before that, I spent many years at NCS, working as a database architect on DBS Bank projects. Tell me about one of the most interesting projects you’ve worked on here While I work with many amazing customers, the project I cherish the most is an in-house developed tool that automates ScyllaDB Enterprise/Cloud/X Cloud clusters with a single command, allowing the user to run various workloads and perform stress testing of multiple clusters. This is the ScyllaDB Automation Framework, and I have worked on this project for more than a year. This helps various team members in ScyllaDB with their day to day tasks, whether running a demo for a customer or simulating a customer use case. What’s the most impressive ScyllaDB feat you’ve seen a team accomplish If we talk about teams in ScyllaDB, X Cloud is an amazing ScyllaDB product that lets customers save costs while running at any scale. The team has done an outstanding job. Talking about customers, every one of them is unique in some way. JioStar from India uses ScyllaDB to support IPL, World Cup Cricket, and many other supporting events where millions of users concurrently log in to ScyllaDB clusters through their app — and ScyllaDB handles them gracefully without any lags. There are many others, but I can’t mention everyone. What do you like to do when you’re not working or on-call I spend time with my wife at home, go out for long walks, watch movies, and care for two bunnies who have been with us for more than 5 years. What’s your top tip for getting the most out of ScyllaDB I can’t recommend just one thing, but ScyllaDB is designed to run almost on autopilot. Rarely is there a need to tune any aspect of the ScyllaDB cluster. But if I had to pick one thing, it would be “proper NoSQL data modeling.” I have seen many teams struggle with performance because they had a poor data model. After spending some time with them and helping them fix their data model mistakes, their ScyllaDB cluster ran smoothly with the promised single-digit P99 latencies. I recommend everyone to join ScyllaDB University (it’s free) and take the beginner and advanced data modeling courses.

ScyllaDB Operator 1.21 Release — with Oracle Kubernetes Engine (OKE) Support

10 June 2026, 4:03 pm by ScyllaDB

Introducing Oracle Kubernetes Engine support, stronger TLS, and a lighter dependency footprint ScyllaDB Operator 1.21.0 is now available. For background, ScyllaDB Operator is an open-source project that helps you run ScyllaDB on Kubernetes. It lets you manage ScyllaDB clusters deployed to Kubernetes and automate tasks related to operating a ScyllaDB cluster (e.g., installation, vertical and horizontal scaling, as well as rolling upgrades). ScyllaDB Operator 1.21 expands cloud platform support with OKE, adds ECDSA as an alternative key type for TLS certificates, and removes a hard dependency on Prometheus Operator. Oracle Kubernetes Engine (OKE) support ScyllaDB Operator 1.21 adds Oracle Container Engine for Kubernetes (OKE) as a supported platform. The new OKE support comes with comprehensive documentation covering the entire workflow , from provisioning the underlying OCI infrastructure (VCN, subnets, gateways, and node pools with Dense I/O shapes and local NVMe storage) to deploying a 3-node ScyllaDB cluster spread across fault domains. An automated setup script is also provided for one-command infrastructure provisioning. To get started with ScyllaDB on OKE, see the Set up an OKE cluster for ScyllaDB infrastructure guide and the OKE reference deployment. ECDSA support for TLS certificates ScyllaDB Operator manages TLS certificates internally for securing client-to-node communication. Until now, only RSA keys were supported for certificate generation. ScyllaDB Operator 1.21 adds elliptic curve cryptography (ECDSA) as an alternative key type. This allows smaller key sizes and faster cryptographic operations with strong security. You can opt in to ECDSA by setting the –crypto-key-type=ECDSA flag on the operator, with the curve bit-size configurable via –crypto-ecdsa-key-size (defaulting to P-384). RSA remains the default key type. The RSA key size is now configured with a dedicated –crypto-rsa-key-size flag; the previous –crypto-key-size flag is deprecated and remains accepted as an alias. Prometheus Operator is now an optional dependency Previously, ScyllaDB Operator required Prometheus Operator CRDs (monitoring.coreos.com/v1) to be installed in the cluster, even if you did not intend to use ScyllaDBMonitoring. Missing CRDs would result in error logs at startup. With ScyllaDB Operator 1.21, Prometheus Operator becomes a purely optional dependency. The operator auto-detects whether the CRDs are present at startup using Kubernetes API discovery. When they are absent, the ScyllaDBMonitoring controller is not started and no error logs are emitted. If you install Prometheus Operator after the ScyllaDB Operator is already running, restart the operator to pick up the new CRDs. Refer to the monitoring setup guide for details.

Dear cqlsh: Your dependencies were killing us (P.S. We rewrote you in Rust)

2 June 2026, 12:35 pm by ScyllaDB

A story of rewriting cqlsh in Rust…with Claude Code and a lot of planning Dear cqlsh, I vouched for you. I told the team you were fine. I forked you, catered to you, vendored your dependencies and your dependencies’ dependencies. I patched things upstream that I knew you would never merge. I pinned your Python, re-pinned it after the OS upgraded, and explained to people (with a straight face) why that was totally normal and not a problem at all. I wrote you twice already. You never wrote back. I’m not even mad. I get it: you’re busy. 30+ CLI flags, 25 CQL types, a COPY engine with enough options to fill a man page…You’ve got a lot going on. But I found someone faster, someone who compiles to a static binary without a runtime, without vendoring. They don’t make me think about “which Python are we using today?” They just…work. I hope you understand. Yours (for now), Israel This is the story of cqlsh-rs – a ground-up Rust rewrite of the Python cqlsh, the interactive CQL shell used daily by everyone working with Cassandra and ScyllaDB. It’s also a story about what happens when you take the lessons from one AI-assisted project and apply them to another project. Why bother rewriting? Because packaging is a nightmare. ScyllaDB ships a relocatable package, a self-contained bundle with its own Python runtime baked in. The system Python can change, upgrade, or disappear entirely, and ScyllaDB’s startup scripts and cqlsh keep working because they’re running against a known, pinned Python version inside the bundle. Except cqlsh has to live inside that bundle. And cqlsh is a Python tool. It has dependencies, those dependencies’ dependencies have dependencies, and they all need to be vendored in alongside the bundled Python. Every time cqlsh or one of its dependencies needs updating (a bug fix, a new Cassandra protocol version, a security patch), you need to update the bundle, test the bundle, and ship the bundle. And if something conflicts or breaks inside that carefully pinned environment, it’s your problem to untangle. A static Rust binary sidesteps all of this. You compile once per target, you get a single file with zero runtime dependencies, and you ship it. Done. The second pain point is COPY TO/FROM, cqlsh‘s built-in feature for bulk-exporting and importing table data to CSV. It’s one of the most-used features, and it’s been carrying around a long list of bugs for years. It does have parallel workers (threads and processes), but the machinery is complicated, fragile, and notoriously hard to test. The bug list reflects that. Both of these are solvable in Rust. So, the question became: is now the time to actually solve them? It all started with a BIG plan (to the tune of The Big Bang Theory) In a previous post, I wrote about using GitHub Copilot to bring a 4-year-old Python idea (coodie, a Pydantic ODM for Cassandra) back to life. That project was relatively contained: give the AI a concept, come back to a working implementation. Fire and forget it, more or less. cqlsh-rs is a different category of project. The original Python cqlsh has been around for over a decade. It has hundreds of CLI flags, a compatibility matrix that spans multiple database versions, a COPY engine with 30+ options per direction, tab completion that must be schema-aware, and a type system covering 25+ CQL types with specific formatting rules. Shipping something that “mostly works” is not good enough if people are going to actually switch to it. Every muscle-memory command has to work the same way. So before writing a single line of Rust, I started with a plan. That plan started as one document. It grew, then it became a master design document plus sub-plans. By the time the architecture settled, there were 19 sub-plans (SP01 through SP19) covering everything from the CLI argument parser to the CQL type formatter to the COPY engine to a future --ai-help flag for offline CQL error diagnostics. Here’s what the roadmap looked like near the start: 5 out of 108 tasks. 0.4 tasks per day. The footer on that SVG read: “Approximately 8.9 months remaining… just like Windows said.” Reader, it did not take 8.9 months. “Wait, why is there a skill for that?” I started in Claude web, but not because that’s my comfort zone. With Copilot, I liked the browser because it made the conversation visible to the team, a kind of shared thinking space. I had the same instinct here. This way, design conversations, architecture decisions, trade-off explorations, etc all happened in the browser before a single file was created. Questions like What driver to use? How to structure the CLI argument parsing? Should we write a hand-rolled CQL parser or keep it simple with a line-buffer approach? are genuinely better answered in conversation than in code. The master plan came together there. So did the first sub-plans and the initial CI skeleton. Then I started exploring Claude Code, the CLI. Somewhere around phase 2, I closed that browser tab once and for all. One reason is the feedback loop: you’re in the same environment as the code, so cargo test runs immediately after a change, failures surface in context, and the next prompt can reference the actual output. Another reason is just familiarity: the more you use it, the more you learn to point it at exactly the right problem. Skills: write your conventions once, use them forever The skills library was also critical for this project: /rust-testing – What to test at the unit layer vs. the integration layer, how to use assert_cmd for CLI tests, when to reach for insta snapshots /rust-clippy – Run Clippy with strict settings and fix everything it complains about /rust-error-handling – Idiomatic error handling patterns for this codebase /development-process – The full loop: review the relevant sub-plan, design tests first, implement, run tests, update the plan, commit I carried the pattern directly from coodie. The specific skills are different (Python vs. Rust), but the idea is the same. Each skill you write makes every subsequent feature cheaper to build. Living documents (or, an outdated plan is worse than no plan) The 19 sub-plans are living documents that are updated when decisions are made (vs written upfront and then abandoned, like most docs). When a design decision changes mid-implementation, the plan changes too. When a task is done, the checkbox gets ticked. When a new edge case surfaces, it gets added. This matters more than it might seem. An outdated plan is worse than no plan because the AI will follow it faithfully…in the wrong direction. What’s in the box Nothing terribly exotic; there’s: Rust with Tokio for async. The scylla crate for the database driver. rustyline for the REPL and line editing. comfy-table and owo-colors for output formatting. testcontainers-rs for spinning up real Cassandra instances in CI. While the stack itself might not be exciting, the interesting part is what it takes to get every CQL type to format exactly like the Python implementation – right down to float precision and frozen collection syntax. That’s where most of the compatibility work lives. Where are we now? Here’s the same roadmap today: Phases 1 through 3 are done. The shell works: you can… Connect Run queries Get formatted output with colors and pagination Tab-complete keyspace and table names Run DESCRIBE on anything Use SOURCE to execute a file Phase 4 – COPY TO/FROM – is implemented. Phase 5 (testing) is in progress, with 327 tests and counting. Takeaways Planning pays (but living documents are a nice touch). A static plan written at the start and never touched again is a liability. A plan that gets updated as decisions are made is an asset – and the primary reason Claude can work effectively across multiple sessions on a project this size. Skills compound. A good amount of work is required to find the right skill for the task and adapt it to the project: the conventions, the patterns, the “this is how we do it here” info. But once that’s written down, it becomes easier to implement every feature. The workflow is never done. The pace of this space is genuinely disorienting. We now regularly use tools that didn’t even exist six months ago. This means that what works today might not work in a month. It’s still writing code, just differently. (I have a bit of trouble using the word “engineering” here.) Claude doesn’t replace judgment on architecture, on what actually matters to users, on “is this the right trade-off?” It removes the friction between having a clear idea of what you want and that thing existing. Whether that makes it better or worse probably depends on the day. Lessons from one project carry over to the next. The skills pattern from coodie was carried into cqlsh-rs with a different language and a different domain. You can start from what you already learned, and the AI follows the same process docs that you wrote last time. Things to look forward to One idea that popped up during this: an --ai-help flag that embeds a small local model to give offline diagnostics when your CQL query fails. In other words, building an AI-assisted tool with an AI assistant that will assist with AI-assisted queries. I’m going to stop thinking about that too hard. 😉 For the model routing, we’ll probably use LiteLLM. I heard it’s become quite popular lately. I had fun. Claude had fun too, probably. I didn’t ask.