Power BI with DuckDB, 4 years later

Four years ago I wrote a blog about using DuckDB with Power BI in DirectQuery. It got a fair number of likes on LinkedIn 🙂 along with the one comment I didn’t want to hear: how does this work in production? (Craig, if you’re reading this, you were right.)

Back then I thought the technology was the hard part and the rest would sort itself out. It didn’t.

The ODBC driver never really worked in any non-trivial setup. Filters didn’t push down, decimal precision was buggy. It has gotten better since, but two show stoppers remained:

  • DuckDB is in-process, so the driver is the database. There’s no warm, long-running session. Every query starts from scratch.
  • I don’t think those drivers can realistically be certified (personal opinion). And Power BI Service, or any hosted BI service for that matter, is not going to host an in-process engine for free. An on-prem data gateway is not really a good option either.

In 2026 things are way better. MotherDuck (DuckDB’s SaaS) shipped a PostgreSQL endpoint. Problem solved: Power BI speaks Postgres, and it works out of the box.

Then last week DuckDB released Quack. For my own sanity I’ll just call it “DuckDB Server.” It is just an extension; a single function call and you have a server !!

My first reaction was annoyance. Four years of waiting, and they shipped a proprietary wire protocol. I was hoping for pg wire. I want my driver to work. I don’t really care about a 2x improvement if nothing interoperates.

Luckily I was partially wrong. Within two days there was an ADBC driver from gizmodata/adbc-driver-quack, and, to my surprise, a Power BI custom connector from Curt Hagenlocher (think of him as the Linus of Power Query). my understanding it is a side project, not official Microsoft.

And somehow, the whole thing worked. It was beautiful.

But lesson learned from last time: this is experimental, with no guarantee the connector will ever be certified.

The main change from the 2022 post is that instead of pointing at parquet files, I’m pointing at a catalog and getting tables back, like an actual database instead of a pile of files and duckdb got way better.

High level architecture

  1. OneLake Iceberg Catalog — OneLake exposes data as tables. You need three things:
    • Endpoint: https://onelake.table.fabric.microsoft.com/iceberg
    • An Entra ID auth token
    • Path to the Lakehouse/Warehouse: workspace_name/Lakehouse_name.Lakehouse

  1. DuckDB + iceberg extension — reads the catalog and the underlying parquet over HTTPS.

  1. Entra IDaz account get-access-token --resource https://storage.azure.com/ mints a short-lived bearer token. No service principal, no app registration. I have a script that grabs the token, and I opened duckdb-azure#170 hoping to make this much simpler.

  1. DuckDB Endpoint — turns the engine into a TCP server on 127.0.0.1:9494, speaking DuckDB’s native wire protocol (whatever that means).

  1. The ADBC Driver — Python client and Power BI share the same DLL, you need to manually install it from curt github page

You can download all the files here

Power BI

Let’s just share a video. Yes, 600M rows, warm run in my laptop

Python Notebook

TPC-H SF=10 (10 GB), 22 queries, run twice in the same session via client.ipynb. Numbers are seconds, copied straight from the notebook output.

ColdWarm
Total~5 min 29 s~30 s

Cold time is dominated by parquet I/O over HTTPS from OneLake. Bandwidth and seek count, not CPU. Warm runs hit DuckDB’s in-process buffer cache, Onelake endpoint is in another continent and my internet provider is horrible 🙂

Optimization on this stack should target bytes read and seeks (codec, row-group size, predicate pushdown, range prefetch), not query plans.

This is exactly why server mode make sense, as the warm cache is shared by all client (notebook, Power BI, AI Agent)

Not production ready

  • The Entra token has a ~1h TTL. As far as I can tell, DuckDB has no way to auto-refresh tokens.
  • The driver is not certified, so it can’t be used in the service, if you want it added to PowerBI, create an idea in Fabric forum and vote
  • DuckDB Server is new. Don’t expect SQL Server maturity yet 🙂
  • DuckDB’s remote file cache is RAM only. When you restart DuckDB, you lose it and have to deal with the cold-run pain again and egress fees 😦
  • The DuckDB Azure extension is still pretty rough in places. To be fair, they’ve openly said they don’t have the bandwidth.

Hopefully it won’t take another four years to make this production ready.

Still, seeing DuckDB as a single binary serving a 600M row table to Power BI was genuinely fun. and The Iceberg catalog is awesome !!!

Ensuring safe single-writer for DuckLake on OneLake using file lease

DuckLake supports multi-writer just fine — but only if your catalog is a real database, like Postgres (there’s some interest in SQL Server support too). But if all you have is object storage and a SQLite or DuckDB file as the catalog, you’re stuck with single-writer: object stores aren’t real filesystems, so the DB file can’t be locked. Nothing stops two processes from writing to it at the same time and corrupting it.

If single-writer is enough for you (one notebook, one pipeline, one user), you don’t need to stand up a database server. You just need accidental concurrent runs to fail fast.

The trick: take a blob lease

OneLake speaks the ADLS API, so you can take a lease on a blob — a mutex for free (it seems S3 needs DynamoDB and GCS needs a homemade lock object). Each run does:

  1. Acquire a lease on metadata.db in abfss://.
  2. Download it to local disk of the notebook.
  3. Point DuckLake at the local copy and do the work.
  4. Upload the modified file under the lease.
  5. Release the lease.

A second notebook that starts while the lease is held fails immediately on acquire_lease. It can’t even read a stale copy. and you can’t delete the file using the UI , I can see already some uses cases here:)

What about crashed runs?

ADLS leases are either 15–60 seconds fixed, or infinite. Fixed leases need a heartbeat — annoying inside a notebook. Infinite leases work until something crashes — then the file is stuck.

The fix: take an infinite lease, but stamp acquired_at = <utc iso> into the blob’s own metadata when you acquire. When the next run hits a lease conflict, read that timestamp. Older than 12 hours? Call break_lease and re-acquire. A crashed run self-heals within 12 hours. You can shorten that window, or break the lease manually with a one-line script if you can’t wait — there’s a snippet in the README.

Code is here.

The Boring Reason Iceberg Matters

TL;DR: Iceberg’s value is sociological, not technical. And if you care about lightweight, single-process engines like datafusion and duckdb, it’s probably your best shot at first-class lakehouse support with Wide interoperability.

The first real data engineering work I did was an ingestion pipeline built on pandas and Parquet with Hive-style partitioning — an environment where 512 MB of memory was a genuine architectural constraint, not a rounding error. That experience shaped how I think about data tooling: the engine matters, but so does the ability to swap it out. Engine independence is something I care about more than most people I know, which is probably why I find myself paying close attention to Iceberg. Not for the reasons most people cite, though. It’s not the spec. It’s where the engineering hours are landing.

Getting query engines and catalogs to talk to each other is genuinely hard work. Most of it is unglamorous: error envelope parsing, metadata round-tripping, commit response shapes, partition spec edge cases, auth token quirks between vendors. None of it ships a feature anyone demos. None of it makes a good blog post. It’s the maintenance work that quietly determines whether your stack actually functions.

This is the part that’s easy to miss. Standards don’t converge because the spec is good. They converge because enough people, at enough companies, decide to put sustained hours into the interop bugs — year after year, across release cycles, through personnel changes and shifting priorities.

Look at the Iceberg committer list: Netflix, Apple, Databricks, Snowflake, AWS, Dremio, Microsoft. No single employer controls what gets merged. The incentive to fix cross-vendor interoperability bugs is distributed across the committer base itself. The governance isn’t just a formality — it’s what makes it possible for engineers from genuinely different setups to find, reproduce, and fix the same bug together.

There is one specific layer worth watching: the Iceberg REST catalog specification. It has become the canonical standard for how engines and catalogs communicate. Adoption is real: Polaris, lakekeeper, Gravitino, and a growing list of vendor-managed catalogs implement it.

But adoption and interoperability are not the same thing.

In practice, vendors still interpret parts of the specification differently. Engines end up handling quirks like slightly different response shapes, undocumented authentication flows, or inconsistent error handling. The nearest analogy is ODBC — a real standard, widely implemented, and still years of painful work before the “connect to anything” promise actually held up in practice.

The Iceberg REST catalog ecosystem feels earlier in that curve. The gap between specification and implementation is exactly where a lot of the maintenance work is happening right now. And closing that gap is precisely the kind of work Iceberg’s governance model is designed to support, because the people hitting the bugs are often the same people with commit access to fix them.

This is where the stakes become concrete, especially for lightweight engines.

For cloud warehouses and large JVM-based systems, the maintenance burden is manageable. There are full-time teams paid to absorb it. For the newer generation of small, single-process engines, the situation is very different. These are compact teams building engines with a specific focus: query latency, memory efficiency, embedded analytics, local execution.

Every hour spent chasing interoperability edge cases is an hour not spent improving the engine itself.

Several of these engines already support Iceberg in some form. But broad, reliable lakehouse support depends on the ecosystem doing its part: stable specifications, faithful implementations, bugs surfaced and fixed upstream.

A well-maintained standard is not just a convenience for these projects. It’s what makes serious lakehouse support achievable without hollowing out the team building the engine.

There is also a broader cost to fragmentation that rarely gets discussed directly. Every hour the ecosystem spends maintaining incompatible metadata layers is an hour not spent making lakehouse systems actually better. That cost doesn’t show up clearly in any individual issue tracker, but it accumulates across the entire ecosystem.

That’s the real argument for Iceberg.

Not that it’s a particularly clever format. Formats are mostly boring by design.

The real advantage is that Iceberg has assembled the right kind of maintenance coalition: enough companies with genuinely different incentives, governance that distributes merge authority, and enough independent implementations that bugs surface from the edges instead of only the center.

Whether that coalition survives long term as the market consolidates is still an open question. But right now, Iceberg is the ecosystem where the boring interoperability work is most likely to get done by someone other than you.

And in infrastructure, that’s close to everything.

That’s also why this feels personal to me.

The 512 MB pipeline I started with wrote Parquet files and hoped for the best — no transactions, no snapshot isolation, just partitions and careful scheduling to avoid stepping on yourself.

What I actually wanted, and couldn’t realistically have at the time, was proper ACID semantics with snapshot isloation end to end from something small and cheap. A cloud function. A tiny process with almost no memory to spare.

Iceberg is the closest thing to a realistic path toward that today. Not because the specification is especially elegant, but because it’s where the maintenance work is happening.

And eventually, ecosystems catch up to where the maintenance happens.

Special thanks to Raki Rahman for a few conversations that genuinely reshaped how I think about this space.

Ideas are mine; writing assisted by AI.

Dynamic Vertical Scaling in Microsoft Fabric Python Notebooks

Microsoft Fabric lets you dynamically configure the number of vCores for a Python notebook session at runtime — but only when the notebook is triggered from a pipeline. If you run it interactively, the parameter is simply ignored and the default kicks in.

This is genuinely useful: you can right-size compute on a job-by-job basis without maintaining separate notebooks. A heavy backfill pipeline can request 32 cores; a lightweight daily refresh can get by with 2.

How It Works

Place a %%configure magic cell at the very top of your notebook (before any other code runs):

%%configure
{
    "vCores":
    {
        "parameterName": "pipelinecore",
        "defaultValue": 2
    }
}

The parameterName field ("pipelinecore" here) is the name of the parameter you’ll pass in from the pipeline’s Notebook activity. The defaultValue is the fallback used when no parameter is provided — or when you run the notebook interactively.

Fabric supports vCore counts of 4, 8, 16, 32, and 64. Memory is allocated automatically to match.

Wiring It Up in the Pipeline

In your pipeline, add a Notebook activity and open the Base parameters tab. Create a parameter named pipelinecore of type Int and set the value to @item().

When the pipeline runs, Fabric injects the value into %%configure before the session starts.

A Neat Trick: Finding the Right Compute Size

Because the vCore value is just a pipeline parameter, you can use a ForEach activity to run the same notebook across multiple core counts in sequence — great for benchmarking or profiling how your workload scales.

Set up a pipeline variable cores of type Array with a default value of [64,32,16,8,4,2]:

Then configure the ForEach activity with:

  • Items: @variables('cores')
  • Sequential: ✅ checked (so runs don’t overlap)
  • Concurrency: 1

Inside the ForEach, add a Notebook activity and set the pipelinecore base parameter to @item(). Each iteration picks the next value from the array and passes it to the notebook, so you get a clean sequential run at 64, 32, 16, 8, 4, and 2 cores.

and of course the time, always change it to a more sensible value

What the Numbers Say

Running the previous workload across all supported core counts produced these results:

CoresDuration
648m 24s
328m 46s
169m 18s
811m 17s
4Failed
2Canceled

The answer here is 8 cores. Yes, it’s about 2 minutes slower than 16 , but it’s half the compute. Going from 64 down to 8 cores costs you less than 3 minutes of runtime, which is a reasonable trade. Below 8 the workload simply falls apart. The sweet spot is not always the fastest run; it’s the point where adding more cores stops meaningfully improving the result.

btw for the CU consumption, the formula is very simple

nb of cores X 0.5 X active duration

Notice you will not be charged for startup duration.

Another Workload: 158 GB of CSV with DuckDB

To make this concrete, here’s a second run — an ETL notebook processing 158 GB of CSV files using DuckDB 1.4.4, the default version available in the Fabric Python runtime.

I’d pick 16 cores here. The jump from 16 to 64 saves you barely a minute and a half — well within the noise, as 16 actually outran 32 in this test. Below 8 cores the runtime climbs steeply, roughly doubling at each step. The reason is that 158 GB of CSV is largely an I/O-bound workload: DuckDB parallelises reads aggressively, but at some point you’re just waiting on storage, not on CPU. More cores stop helping.

Two things worth noting. First, 2 cores completed the job — which is remarkable given that 2 cores comes with only 16 GB of RAM for a 158 GB dataset. DuckDB’s out-of-core execution handled it, but at 1h 10m it pushed close to the limit. And that brings up the second point: OneLake storage tokens have a lifetime of around one hour. A run that creeps past that boundary risks losing access mid-execution. For a workload this size, anything below 8 cores is probably not worth the gamble.

A Word of Caution: Startup Overhead

Before you start bumping up core counts, there’s an important trade-off to keep in mind: anything above 2 cores adds several minutes of python runtime just to provision the session — and that startup time is included in your total duration. For large, long-running workloads it barely registers. For small ones it can easily dominate the total run time.

And most real-world workloads are small. A daily incremental load, a lookup refresh, a small aggregation — these often complete in under a minute of actual computation. If the session startup costs you 3 minutes and the work itself costs 30 seconds, more cores aren’t helping.

The default of 2 cores starts fast and is the right choice for the majority of jobs. Reach for more only when you’ve measured that the workload actually benefits from it.

Beyond Benchmarking: Dynamic Resource Allocation

The benchmarking pattern is useful, but the more powerful idea is using this in production. Because the vCore count is just a number passed through the pipeline, nothing stops a first stage of your pipeline from deciding what that number should be.

Imagine a pipeline that starts by scanning a data lake to count the number of files or estimate the volume of data to process. Based on that output, it computes an appropriate core count and passes it to the notebook that does the actual work — 4 cores for a small daily increment, 32 for a full month’s backfill, 64 for a one-off historical load. The notebook itself doesn’t change; the compute scales to the workload automatically.

This kind of adaptive orchestration is normally something you’d build a lot of custom logic around. Here it’s just a parameter.

The Catch: Interactive Runs Use the Default

This only works end-to-end when triggered from a pipeline. Running the notebook manually in the Fabric UI will silently use the defaultValue — there’s no error, the parameter just won’t be overridden. Keep that in mind when testing.

Tested on Microsoft Fabric as of April 2026. Official reference: Develop, execute, and manage notebooks and Python experience on Notebook.

Special thanks to a colleague from Engineering for sharing this technique. Written with the help of Claude.