Category: Power Query

When Can Partitioned Compute Help Improve Fabric Dataflow Performance?

Partitioned Compute is a new feature in Fabric Dataflows that allows you to run certain operations inside a Dataflow query in parallel and therefore improve performance. While UI support is limited at the moment it can be used in any Dataflow by adding a single line of fairly simple M code and checking a box in the Options dialog. But as with a lot of performance optimisation features (and this is particularly true of Dataflows) it can sometimes result in worse performance rather than better performance – you need to know how and when to use it. And so, in order to understand when this feature should and shouldn’t be used, I decided to do some tests and share the results here.

For my tests I created two queries within a single Dataflow Gen2 CICD. First, an M function called SlowFunction that takes a numeric value and returns that value with 1 added to it after a two second delay:

(input as number) as number => 
Function.InvokeAfter(()=>input+1, #duration(0,0,0,2))

Then the main query which returns a table of ten rows and calls the SlowFunction M function once per row:

let
  Rows = List.Transform({1 .. 10}, each {_}), 
  MyTable = #table(type table [RowNumber = number], Rows), 
  #"Added custom" = Table.TransformColumnTypes(
    Table.AddColumn(MyTable, "FunctionOutput", each SlowFunction([RowNumber])), 
    {{"FunctionOutput", Int64.Type}}
  )
in
  #"Added custom"

Here’s what the output of the query looks like:

Now, the first important question. How long does this Dataflow take to run? 10 rows calling a function that takes 2 seconds to run, so 10*2=20 seconds maybe? The answer is yes if you look at how long the preview takes to populate in the Dataflow Editor:

That’s just the preview though. If you’re refreshing a Dataflow there are other things that happen that affect how long that refresh takes, such as Staging and loading the data to a destination. There’s no way you can split the performance of your M code from these operations when looking at the duration of a Dataflow refresh in Recent Runs, which explains why some of the timings you will see later in this post seem strange. Don’t worry, though, it doesn’t stop you from seeing the important trends. I’m told that setting a CSV file in a Lakehouse as your data destination is the best way of minimising the impact of loading data on overall refresh durations but at the time of writing the CSV destination can’t be used with Partitioned Compute so all my tests used a Fabric Warehouse as a destination.

Here’s what Recent Runs showed when this Dataflow was refreshed:

The overall refresh time was 59 seconds; the query (called NonPartitioned here) that returns the table of ten rows and which was staged took 29 seconds.

Could this Dataflow benefit from Partitioned Compute? With Partitioned Compute enabled in the Options dialog, I added the necessary M code to the query:

let
  Rows = List.Transform({1 .. 10}, each {_}), 
  MyTable = #table(type table [RowNumber = number], Rows), 
  #"Added custom" = Table.TransformColumnTypes(
    Table.AddColumn(MyTable, "FunctionOutput", each SlowFunction([RowNumber])), 
    {{"FunctionOutput", Int64.Type}}
  ), 
  ReplacePartitionKey = Table.ReplacePartitionKey(#"Added custom", {"RowNumber"})
in
  ReplacePartitionKey

…and then refreshed. Here’s what Recent Runs showed:

The overall refresh duration went up to 1 minute 25 seconds; the query that does all the work (called Partitioned in this case) took 40 seconds. Note the screenshot immediately above shows the engine used is “PartitionedCompute” and that there are now ten activities listed instead of one: my M code used the RowNumber column in the table as the partition key so the Dataflow attempted to run each row of the table as a separate operation in parallel. And as you can see, this made performance worse. This is because using Partitioned Compute introduces yet another overhead and that overhead is much greater than any benefit gained from parallelism in this case.

So I wondered: what if the delay in the query is increased from 2 second to 100 seconds then? Does this increase in the delay mean that parallelism results in faster overall performance?

Here’s what Recent Runs showed for a version of my Dataflow with a 100 second delay for each row and which didn’t use Partitioned Compute:

10 rows * 100 seconds = 1000 seconds = 16 minutes 40 seconds, so it’s not surprising that the overall duration of this version of the Dataflow was slow at 17 minutes 29 seconds.

Here’s what Recent Runs shows for the version of this Dataflow that did use Partitioned Compute:

The overall duration was 4 minutes 41 seconds and the main query took 3 minutes 14 seconds. The important takeaway is that this is a lot faster than the version that didn’t use Partitioned Compute, so clearly Partitioned Compute made a big difference to performance here. As you might expect, it looks like parallelising operations that only take a few seconds results in worse performance while parallelising operations that take longer, say a minute or more, is probably a good idea. As always, you’ll need to test to see what benefits you get for your Dataflows.

These results raise a lot of questions too. 100 seconds = 1 minute 40 seconds, which is a lot less than 3 minutes 14 seconds. Does this mean that not every row in the table was evaluated in parallel? Is partitioning on the RowNumber column counter-productive and would it be better to partition in some other way to try to reduce the amount of attempted parallelism? Is there something else that is limiting the amount of parallelism? While this version of the Dataflow always performs better than the non-partitioned version, performance did vary a lot between refreshes. While these tests show how useful Partitioned Compute can be for slow Dataflows, there’s a lot more research to do and a lot more blog posts to write.

Measuring Power BI Report Page Load Times

If you’re performance tuning a Power BI report the most important thing you need to measure – and the thing your users certainly care about most – is how long it takes for a report page to load. Yet this isn’t something that is available anywhere in Power BI Desktop or in the Service (though you can use browser dev tools to do this) and developers often concentrate on tuning just the individual DAX queries generated by the report instead. Usually that’s all you need to do but running multiple DAX queries concurrently can affect the performance of each one, and there are other factors (for example geocoding in map visuals or displaying images) that affect report performance so if you do not look at overall page render times then you might miss them. In this post I’ll show you how you can measure report page load times, and the times taken for other forms of report interaction, using Performance Analyzer in the Service and Power Query.

Consider the following series of interactions with a published Power BI report:

The report itself isn’t really that important – just know that there are a series of interactions with a slowish report while Performance Analyzer is running. Here’s what Performance Analyzer shows by the end of these interactions:

Here’s a list of the interactions captured:

  • I changed from a blank report page to a page with a table visual, where the table visual was cached and displayed immediately
  • I then refreshed the table visual on that page by clicking the Refresh Visuals button in the Performance Analyzer pane
  • I changed to the next page in the report and all the visuals on that page rendered
  • I changed the slicer on that new page
  • I clicked on the bar chart to cross-filter the rest of the page

As you can see from the screenshot above, Performance Analyzer tells you how long each visual takes to render within each interaction but it doesn’t tell you how long each interaction took in total. In a lot of cases you can assume that the time taken for an interaction is the same as the time taken for the slowest visual to render, but that may not always be true.

So how can you use Performance Analyzer to measure the time taken for these interactions? How can you measure the amount of time taken to render a page in a report?

To solve this problem I created a Power Query query that takes the event data JSON file that you can export from Performance Analyzer and returns a table showing the amount of time taken for each interaction. Here’s the M code for this query:

let
    Source = Json.Document(File.Contents("C:\PowerBIPerformanceData.json")),
    ToTable = Table.FromRecords({Source}),
    Events = ToTable{0}[events],
    EventTable = Table.FromList(Events, Splitter.SplitByNothing(), null, null, ExtraValues.Error),
    #"Expanded Column1" = Table.ExpandRecordColumn(EventTable, "Column1", {"name", "start", "id", "metrics", "end"}, {"name", "start", "id", "metrics", "end"}),
    #"Expanded metrics" = Table.ExpandRecordColumn(#"Expanded Column1", "metrics", {"sourceLabel"}, {"sourceLabel"}),
    #"Added Custom1" = Table.AddColumn(#"Expanded metrics", "UserActionID", each if [name]="User Action" then [id] else null),
    #"Added Custom2" = Table.AddColumn(#"Added Custom1", "UserActionLabel", each if [name]="User Action" then [sourceLabel] else null),
    #"Changed Type" = Table.TransformColumnTypes(#"Added Custom2",{{"start", type datetime}, {"end", type datetime}, {"UserActionID", type text}, {"sourceLabel", type text}, {"UserActionLabel", type text}}),
    #"Filled Down" = Table.FillDown(#"Changed Type",{"UserActionID", "UserActionLabel"}),
    #"Filtered Rows" = Table.SelectRows(#"Filled Down", each [start] > #datetime(1970, 1, 2, 0, 0, 0)),
    #"Filtered Rows1" = Table.SelectRows(#"Filtered Rows", each [end] > #datetime(1970, 1, 2, 0, 0, 0)),
    #"Grouped Rows" = Table.Group(#"Filtered Rows1", {"UserActionID", "UserActionLabel"}, {{"Start", each List.Min([start]), type nullable datetime}, {"End", each List.Max([end]), type nullable datetime}}),
    #"Added Custom" = Table.AddColumn(#"Grouped Rows", "Duration", each [End]-[Start], type duration),
    #"Removed Columns" = Table.RemoveColumns(#"Added Custom",{"UserActionID"})
in
    #"Removed Columns"

Here’s the output of this query for the interactions shown above:

Some notes about this query:

  • You will need to change the Source step to point to the JSON file you have exported from Performance Analyzer
  • Each interaction is represented by a row in the table and identified by the UserActionLabel column
  • I’m calculating the durations by finding the minimum start time and the maximum end time for all events associated with an interaction and subtracting the former from the latter
  • There’s a bug (which hopefully gets fixed at some point) where some events have start and end dates in 1970, so I have filtered out any dates that are obviously wrong
  • The Duration column shows how long each interaction took and uses the Power Query duration data type, which is formatted as days.hours:minutes:seconds

The example above is fairly complex showing several different kinds of interactions. If you just want to find the amount of time taken to render all the visuals on a page you can click the Refresh Visuals button in Performance Analyzer to refresh all the visuals on the page – it may not give you a 100% “cold cache” page render but it will be good enough. I’m not a web developer but I think to really do things properly you’ll need to open the report on a blank page in the browser, do an “Empty Cache Hard Reload“, go to edit mode in the report, enable Performance Analyzer, then move to the page you want to test. If you’re testing a DirectQuery model then you’ll also want to include the overhead of opening connections (which can be substantial); the only way I have found to do that is either wait for at least an hour for any connections in the pool to be dropped, or if you’re using a gateway to restart it. One last point to make is that while you can use Performance Analyzer in Power BI Desktop and in the browser the behaviour of Power BI may be different in these two places, so always make sure you measure performance of published reports in the browser because that’s where your users will be using your reports.

Here’s what clicking the Refresh Visuals button in Performance Analyzer to refresh all the visuals on a page looks like:

This results in a single interaction and a single row in the output of the Power Query query above:

In this case you can see that the page refresh took 12.14 seconds.

As you will have realised by now, getting the amount of time it takes to load a report page isn’t straightforward and there are a lot of factors to take into account. Nonetheless using Performance Analyzer in this way is much better than not measuring page load times at all or (as I’ve seen some people do) using a stopwatch. If you try this and find something interesting please let me know: I’m doing a lot of testing with Performance Analyzer and learning new things all the time.

Generating Sample Data With Copilot In Fabric Dataflows Gen2

As a Power Query fan I’m naturally interested in Copilot in Dataflows Gen2. But since Power Query is already very easy to use and since I’m pretty experienced at using it, can Copilot really do anything to help me be more productive? Well one thing I need to do a lot for blog posts, demos and testing is to generate tables of sample data. Typing data into the Enter Data source can be quite tedious and writing the M code to generate sample data isn’t straightforward, so I was wondering if Copilot in Dataflows Gen2 could do it for me. It turns out it can do so really well.

After a little bit of experimentation I’ve come up with an example prompt that can be easily modified to return a table of random values with columns of different data types and a given number of rows, and which works fairly reliably:

Return a table consisting of the following five columns: 
Country, containing one of 10 random country names; 
Product, containing one of 15 random fruit names; 
Person, containing one of 20 random first names that are common in the United Kingdom;
Date, containing random dates between January 1st 2019 and December 31st 2024;
Sales, containing random integers between 0 and 500. 
The table should have 1000 rows. Set an appropriate data type for each column.

Here’s an example of the M code generated:

let
    // Generate lists of random values
    Countries = {"United States", "Canada", "United Kingdom", "Germany", "France", "Italy", "Spain", "Australia", "India", "China"},
    Products = {"Apple", "Banana", "Cherry", "Date", "Elderberry", "Fig", "Grape", "Honeydew", "Kiwi", "Lemon", "Mango", "Nectarine", "Orange", "Papaya", "Quince"},
    People = {"James", "Mary", "John", "Patricia", "Robert", "Jennifer", "Michael", "Linda", "William", "Elizabeth", "David", "Barbara", "Richard", "Susan", "Joseph", "Jessica", "Thomas", "Sarah", "Charles", "Karen"},
    StartDate = #date(2019, 1, 1),
    EndDate = #date(2024, 12, 31),
    DaysBetween = Duration.Days(EndDate - StartDate) + 1,

    // Function to generate random dates
    RandomDate = () => Date.From(StartDate + #duration(Number.RoundDown(Number.RandomBetween(0, DaysBetween)), 0, 0, 0)),

    // Generate table records
    Records = List.Transform({1..1000}, each [
        Country = Countries{Number.Mod(_, List.Count(Countries))},
        Product = Products{Number.Mod(_, List.Count(Products))},
        Person = People{Number.Mod(_, List.Count(People))},
        Date = RandomDate(),
        Sales = Number.RoundDown(Number.RandomBetween(0, 500))
    ]),

    // Convert list of records to table and set data types
    Source = Table.FromRecords(Records),
    TypedTable = Table.TransformColumnTypes(Source, {
        {"Country", type text},
        {"Product", type text},
        {"Person", type text},
        {"Date", type date},
        {"Sales", Int32.Type}
    })
in
    TypedTable

And here’s an example of the output:

Definitely a time saver as far as I’m concerned. Is it totally reliable? No: it occasionally produces code that errors or which doesn’t contain genuinely random values, but it’s good enough and it’s faster to try the prompt once or twice than write the code myself. I know there are other, more sophisticated ways of generating sample data like this in Fabric, for example in Python, but as I said I’m a Power Query person.

And of course, for bonus points, we can now send the output of a Dataflow Gen2 to a CSV file in SharePoint which makes this even more useful:

Two New Power BI/Power Query Books

It’s time for another one of my occasional posts about free books that I’ve been given that you might be interested to check out. The usual disclaimers apply: these aren’t impartial, detailed reviews and the links contain an Amazon UK affiliate code so I get a kickback if you buy a copy.

Power Query Beyond The User Interface, by Chandeep Chhabra

Chandeep is of course famous on YouTube from the Goodly Power BI channel; I’ve met him at conferences and he’s just as friendly and passionate in real life. That passion shows through in this book. It’s aimed at people who already know Power Query and want to learn M and while it does a great job of that, I think anyone who writes M on a regular basis would also benefit from reading it. It’s packed with practical examples, well-written, everything is clearly explained and it covers more recent additions to the language that older books might not talk about. It’s focused on the M language and doesn’t cover topics like performance tuning but I think that focus is a good thing. Highly recommended for anyone serious about Power Query.

Architecting Power BI Solutions In Microsoft Fabric, by Nagaraj Venkatesan

It looks like the Packt marketing machine has gone into overdrive for this title because I see both Greg Lowe and Sandeep Pawar have already published their reviews, and I agree with their sentiments. Power BI (and even more so Fabric) is complicated and so there’s a huge demand for guidance around what all of the components do and how to put them together to create a solution. The team I work on at Microsoft, the Fabric CAT team, has a published guidance documentation here and other people have written books, blog posts and white papers addressing the same problem. This book is certainly a very useful addition to the existing literature. It covers newer topics like Power BI Copilot and some topics that are rarely if ever mentioned elsewhere, such as Power BI’s integration with Purview. As the other reviewers have mentioned, books like this always suffer from changes to the product making them out of date very quickly but that’s unavoidable. Also, being written by a Microsoft employee (and this is something I can relate to), it’s not very opinionated and doesn’t tell you which features of the product are good and which ones should be avoided. All in all, pretty good though.

Using Excel Copilot To Import Data With Power Query

Although it was announced in this blog post on the Microsoft 365 Insider blog recently, you might have missed the news that Excel Copilot can now generate Power Query queries. There are limitations for now: it can only be used to connect to other Excel files stored in OneDrive or SharePoint and it can’t do any transformations in the queries it creates, but it’s still exciting news nonetheless. Well the kind of news I get excited by at least.

Since the announcement blog post didn’t give many details of how it works let’s see an example of it in action. Let’s say you have an Excel workbook called SprocketsWidgetsSales.xlsx that contains a table of data showing sales of sprockets and widgets – the products your company sells – by country:

Now let’s say you create a new, blank workbook and open the Copilot pane. Entering the prompt:

Search for data on sales of sprockets and widgets

…gives you the data from the first workbook in the response:

At the bottom you can see a citation reference pointing to the workbook containing the source data and clicking that reference opens that workbook in Excel Online, but we don’t want to do that, we want to load the data into the current workbook using Power Query. Clicking on “Show tables to import” shows a preview of all the Excel tables (in this case there’s only one) in the workbook:

Expanding “Show import query” shows the M code for the Power Query query it can generate:

And clicking “Import to new sheet” creates that Power Query query and runs it:

You can see the Power Query query it creates in the Queries & Connections pane and edit it in the Power Query Editor like any other query:

Here’s the output of the query in a table on a new worksheet:

Of course now you have the table of data on your worksheet you can do other things like:

chart this data by country and product

…or ask questions like:

which country had the lowest sales of sprockets?

…and other things that you’d expect Copilot to be able to do. But the key thing is that Copilot is can now generate Power Query queries! I’m looking forward to see how this feature improves in the future.

Reading Delta Metadata In Power Query

There’s a new M function rolling out now that allows you to read metadata from Delta tables (at the time of writing it’s available in Dataflows Gen2 and will be available soon in Desktop). It builds on the DeltaLake.Table M function that allows you to read data from Delta tables and is similar to the Parquet.Metadata function that was released last year. Here’s an example of how to use it to get metadata from a Delta table in OneLake:

let
  Source = AzureStorage.DataLake(
    "https://onelake.dfs.fabric.microsoft.com/insertworkspaceidhere/insertlakehouseidhere/Tables/inserttablenamehere", 
    [HierarchicalNavigation = true]
  ), 
  ToDelta = DeltaLake.Metadata(
    DeltaLake.Table(Source)
  )
in
  ToDelta

The function returns a table of records containing the metadata from the Delta table such as the schema, how the table is partitioned, and whether the table is V-Ordered or not:

Improve Power Query Performance On CSV Files Containing Date Columns

A few weeks ago I replied to a question on reddit where someone was experiencing extremely slow performance when importing data from a CSV file using Power Query. The original poster worked out the cause of the problem and the solution themselves: they saw that removing all date columns from their query made their Power Query query much faster and that using the Date.FromText function and specifying the date format solved the problem. While I couldn’t reproduce the extreme slowness that was reported I was able to reproduce a performance difference between the two approaches and Curt Hagenlocher of the Power Query team confirmed that this was expected behaviour.

Let’s see an example. I created a CSV file with five date columns and one million rows, then created a Power Query query to import this data into Power BI Desktop using the default M code generated by the Power Query Editor:

let
  Source = Csv.Document(
    File.Contents("C:\GenerateDates.csv"),
    [
      Delimiter  = ",",
      Columns    = 5,
      Encoding   = 65001,
      QuoteStyle = QuoteStyle.None
    ]
  ),
  #"Promoted Headers" = Table.PromoteHeaders(
    Source,
    [PromoteAllScalars = true]
  ),
  #"Changed Type" = Table.TransformColumnTypes(
    #"Promoted Headers",
    {
      {"Extra Spaces", type date},
      {"Extra Spaces - 2", type date},
      {"Extra Spaces - 3", type date},
      {"Extra Spaces - 4", type date},
      {"Extra Spaces - 5", type date}
    }
  )
in
  #"Changed Type"

The dates in the CSV file were in the following format:

02  Jan   1901

…and this is important: there are two spaces between the day and the month name and three spaces between the month name and the year.

Using SQL Server Profiler I found that this query took around 14 seconds to run.

I then created a second query that, instead of using Table.TransformColumnTypes to set the data type on the columns, used Date.FromText and the Format option:

let
  Source = Csv.Document(
    File.Contents("C:\GenerateDates.csv"),
    [
      Delimiter  = ",",
      Columns    = 5,
      Encoding   = 65001,
      QuoteStyle = QuoteStyle.None
    ]
  ),
  #"Promoted Headers" = Table.PromoteHeaders(
    Source,
    [PromoteAllScalars = true]
  ),
  DateConversionFunction = (inputDate) as date =>
    Date.FromText(
      inputDate,
      [Format = "dd  MMM   yyyy"]
    ),
  ChangeDate = Table.TransformColumns(
    #"Promoted Headers",
    {
      {
        "Extra Spaces",
        DateConversionFunction,
        Date.Type
      },
      {
        "Extra Spaces - 2",
        DateConversionFunction,
        Date.Type
      },
      {
        "Extra Spaces - 3",
        DateConversionFunction,
        Date.Type
      },
      {
        "Extra Spaces - 4",
        DateConversionFunction,
        Date.Type
      },
      {
        "Extra Spaces - 5",
        DateConversionFunction,
        Date.Type
      }
    }
  )
in
  ChangeDate

This version of the query took around 10.5 seconds to run, so not a huge improvement but a noticeable one. It’s certainly not the 6/7x performance improvement seen on the reddit post but I’m sure different data, different date formats and different hardware might result in bigger differences.

I was told by Curt that when Power Query uses Table.TransformColumnTypes to parse date data from CSV files it tries a series of different date formats in order: first it tries ISO-8601 (for example 9th February 2025 would be “2025-02-09”), then a long date format, then a short date format, and finally it uses a generic .NET date parsing function which is slower than the others. It does this to make sure date parsing “just works” as often as possible. The dates in the example above, with the extra spaces, were deliberately designed to be slow for Table.TransformColumnTypes. When I tested on CSV files that contained dates in IS-8601 format I found that Table.TransformColumnTypes performed the same as Date.FromText.

So, to sum up, if you’re using CSV files containing date columns as a source for Power Query and you’re experiencing performance problems, try changing your M code to use Date.FromText instead of Table.TransformColumnTypes to set the data types on the date columns.

The “DataFormat.Error: File contains corrupted data” Error In Power Query

When you’re using Excel workbooks as a data source in Power Query in either Excel or Power BI you may encounter the following error when trying to connect:

DataFormat.Error: File contains corrupted data.

There are three possible causes of this error that I know of, two of which are well documented. First, the file may actually be corrupt in which case I hope you have a backup! Second, the Excel file may be password protected. Power Query cannot connect to a password protected Excel file so you’ll need to remove the password protection before you can use it as a source.

The third is one I ran into this week and it confused me a lot. It turns out that if the Excel file has a sensitivity label applied to it that results in it being encrypted, Power Query in Excel will not be able to connect to it – although Power Query in Power BI will be able to. When connecting to an encrypted Excel file, Power Query in Power BI is able to decrypt the file using the credentials of the logged-in user and read it, but (at least at the time of writing) Power Query in Excel cannot do this and so you get the error above. In my case I had an Excel workbook that used Power Query to connect to a few other Excel workbooks, load data from them, and do some tax calculations. It was working a few months ago but when I reopened it this week I got the “DataFormat.Error” error and I couldn’t work out why. It turns out that in the meantime an admin at Microsoft had applied a company-wide policy that meant all workbooks stored in OneDrive for Business had a highly restrictive sensitivity label applied automatically – which means my Power Query queries stopped working. As soon as I changed the sensitivity label on my source workbooks to “Non Business” so they weren’t encrypted, everything worked again.

[Thanks to Curt Hagenlocher for this information]

Module.Versions Function In Power Query

The ever-vigilant folks on the internet have spotted that there’s a new M function in the latest versions of Power BI and Excel: Module.Versions. This function, at the time of writing, returns a record with a single field in that contains the version number of the Power Query engine currently in use. So for example if I have a Power Query query in Power BI Desktop that consists of the following code:

Module.Versions()

It returns the following:

…where 2.129.181.0 is the version of the Power Query engine in my build of Power BI Desktop.

This function was introduced for people developing Power Query custom connectors who only want to enable certain functionality if the user is running a given version of the Power Query engine or above. I guess if you’re sharing your own M custom functions on the internet then you might want to do the same thing.

[Thanks to Curt Hagenlocher for giving me the inside information here]

Power BI/Data Books Roundup

It’s time for another short post on the free books that various authors have been kind enough to send me over the last few months. Full disclosure: these aren’t reviews as such, they’re more like free publicity in return for the free books, and I don’t pretend to be unbiased; also the Amazon UK links have a affiliate code in that gives me a kickback if you buy any of these books.

Deciphering Data Architectures, James Serra

I’ll be honest, I’ve had this book hanging around in my inbox since February and I wasn’t sure what to expect of it, but when I finally got round to reading it I enjoyed it a lot and found it very useful. If you’re looking for clear, concise explanations of all of the jargon and methodologies that are in use in the data industry today then this is the book for you. Do you want to understand the difference between Kimball and Inmon? Get an honest overview of data mesh? Choose between a data lake and a relational data warehouse? It’s all here and more. It’s an opinionated book (which I appreciate) and quite funny in places too. Definitely a book for every junior BI consultant to read and for more senior people to have handy to fill in gaps in their knowledge.

Extending Power BI with Python and R (second edition), Luca Zavarella

I posted about the first edition of this book back in 2021; this new edition has several new chapters about optimising R and Python settings, using Intel’s Math Kernel library for performance and addressing integration challenges. As before this is all fascinating stuff that no-one else in the Power BI world is talking about. I feel like a future third edition covering what will be possible with Power BI and Python in Fabric in 2-3 years will be really cool.

Data Cleaning with Power BI, Gus Frazer

It’s always nice to see authors focusing on a business problem – in this case data cleaning – rather than a technology. If you’re looking for an introductory book on Power Query this certainly does the job but the real value here is the way it looks at how to clean data for Power BI using all of the functionality in Power BI, not just Power Query, as well as tools like Power Automate. It’s also good at telling you what you should be doing with these tools and why. Extra credit is awarded for including a chapter that covers Azure OpenAI and Copilot in Dataflows Gen2.