This post is from a decade old draft where I thought I would write a grand treatise about every bit of wisdom I could possibly impart to other developers. So let this be proof that I absolutely can still write about software development outside of promoting the “Critter Stack” if you give me a decade to finish the post and a day when my new fangled AI agent is being extremely slow!

A lot of my time over the past 15 years has been spent helping other software developers analyze, debug, and fix problems in their own work. I also spend a lot of time working in some fairly complicated problem domains where I not infrequently have to unwind problems of my own creation. It follows pretty naturally that I’ve spent a significant amount of time thinking both about how I debug problems in code and how I would try to teach other developers to be better at debugging their own problems.

Here then is a few thoughts about the act of debugging problems in software systems. You’ll note that I’m not going to talk really at all about specific tools. I’m happy to leave that to other people and really just focus on how you use your noggin to think your way into determining root causes and fixes.

Do what I say, not what I just did…

And of course while I was writing this I wasn’t practicing what I’m preaching, so let’s look at a micro-cosm of all this advice for a problem I was troubleshooting right after I wrote most of this post. Right now I’m focused on a forthcoming product for JasperFx Software named “CritterWatch.” That product will have to manage communication between Wolverine systems, the centralized CritterWatch service and connected CritterWatch browsers. Last week I was initially struggling with why the initial load of the web pages was missing some data from the backend as shown in this diagram:

I was working pretty late in the afternoon waiting for my daughter to wrap up an after school activity, and I admittedly wasn’t at my best. I followed these steps:

1. There were custom value types in the information flow from Wolverine to CritterWatch to the CritterWatch user interface, so I first went with the reasonable theory that there were JSON serialization problems that had cropped up since last I’d worked seriously in this codebase.
2. I was feeling lazy at the end of the day, so I tried to get Claude to “solve” the problem for me and told it to look at serialization issues. Claude claimed to have fixed a problem, but no dice when I ran the whole stack
3. I wasn’t really getting into the whole flow yet, so I kept trying to just add more tests to verify bidirectional JSON serialization and deserialization of the custom types, and all of those new tests were passing just fine.
4. I finally listened to what the feedback was telling me and moved off of what had been my initial theory once I had really disproven that theory about serialization problems several ways to Sunday.
5. I walked away for the night, and came back fresh the next morning
6. After some rest, I went a lot deeper in the code and got back up to speed on how data flowed throughout and with a little more judicious debugging I was able to determine that the data was flowing incorrectly much earlier in the workflow than I’d originally thought and that the problem was very different than I’d first theorized. To use the analogy I’ll introduce in a bit, I took my mental X-Wing right into the trench to go find the thermal exhaust port.
7. Knowing where the problem was, I switched to using automated tests that were finer grained than running the while system end to end and much more quickly repeatable
8. With the faster feedback loop and a new theory about what could be going wrong, I made a change to the internals that turned out to be correct and I got the tests passing before moving on to running the full stack end to end and seeing the whole system function correctly. Finally.
9. And lastly, I actually did remember to go rip out some of the temporary tracing code I’d put in while diagnosing the problems

Does any of this matter if we have LLMs now?

Definitely for the short term and probably for the longer term too? I’ve been very impressed with my usage of Claude Code so far, but I’ve seen plenty of times when I could have probably have solved an issue much faster myself than letting Claude hit it with brute force. Even with a tool like Claude or Copilot, I’d still say you want to feed it what you think the likely cause is to speed up its own work and whatever facts you know. And I guess at the end of the day I just don’t believe an LLM is going to be better than a capable human at everything, especially when you’re facing a novel problem.

I have found it advantageous to have the LLM tools retrofit tests to verify or disprove theories about why code is broken. It’s also been helpful to get an LLM to create summaries of a code subsystem including dumping that out to a markdown file with requested Mermaid diagrams explaining the flow.

Oh, and I absolutely think it’s important for you to understand how the fancy AI tool was able to fix the issue later anyway.

15/15 Minute Rule

Before we get into the real meat of this post, there are two unhealthy behaviors I see from other developers asking for help that drive me absolutely bananas:

1. Not making the slightest attempt to solve their problem on their own before they ask for help, but I think this is commonly caused by developers who can’t do what I’m going to call step 1 below
2. Spending hours banging their head against the wall trying to solve something that I could have helped them get through much more quickly

I really wish I’d made of note who wrote this first — and we can happily quibble about what exactly the time duration should be — but I’d highly recommend the “15/15 Rule” of debugging. You should spend at least 15 minutes trying to debug a problem on your own both to develop your own skills and to keep from overloading your colleagues and maybe causing them to resent you. After that though, spend no more than 15 more minutes trying to solve the problem before you lift your head up and ask someone else for help.

It’s been years since I have been an active development lead, but I vividly remember how frustrating either extreme can be. At the time I started this post I was a remote “architect” who was on call to help anyone who could reach me on Hipchat (I think? Long before Slack), and I tried to take that role seriously. Now, one very important thing I should have taken more seriously then and that I have tried to impart to technical leaders since is that you should try really hard to teach the other people on your team how you debugged the problem and found the eventual answer. That could include knowing to check certain log files, database tables, or just imparting more about how the system works.

And of course, there were days when I wished fewer people needed my help on any given day. Then a few years later that company hired a lot more people in the main office with a few senior folks mixed in and people stopped asking me for help altogether. And if you are assuming that probably led to me no longer working there, you’d probably be at least partially right.

Step 1: Believing that you can figure it out

I despise touchy feely, kumbayah statements in regards to software development, but I do actually think that believing that you can understand the problem you’re facing and fix it is the all important first step. If you stay on the outside and just randomly try different things without understanding what you’re dealing with or try to set Debugger breakpoints in what you hope might be a useful spot, you might get lucky, but in my experience that’s not a sure thing.

Look, I’m solidly GenX, so the analogy I’m going to make is trying to destroy the Death Star. Sure, you can try to lob shots from the outside, the only sure way is to go fly your X-Wing right through that trench until you find the thermal exhaust port that will blow up the whole thing.

Long story short, I think you need to be ready to roll your sleeves up and learn enough about whatever it is you’re working on to have a good enough mental model of how information flows and where the points are that the process could be failing.

Oh, and another important point. Experience helps tremendously in debugging problems, and the only way to get experience is to try to debug problems yourself or at least just not ask the older dev on your team to just fix it for you.

Create a Mental Model

Okay, so once we actually believe that we can ultimately understand the code, the problem, and the eventual solution, I suggest you create or refresh your own mental model of how the code that’s failing works. I’d say to first focus on:

• Where, when, and how system state is mutated
• The workflow of the code or system or systems in play. How does information pass between elements of the code or the system?

What I think specifically you’re looking for is the most likely place in that workflow where things are going wrong and that you should…

One thing I already like AI for is to quickly say “make me a summary of XYZ code in markdown with a Mermaid sequence diagram for ABC.”

Have a Theory, then Prove or Disprove It

Formulate the most likely theory about why the functionality is failing and devise some way to verify or disprove that theory. Sometimes you can do this through targeted Debugger usage, but I’ll also highly recommend trying to build automated tests to verify intermediate steps as that’s almost always going to be a much faster feedback cycle than manually running through a system or series of systems. To put this more bluntly, always be looking to shorten your debugging session by looking for faster, finer grained feedback cycles that can tell you something valuable. And of course, absolutely leave behind automated test coverage as regression tests against whatever the problem turns out to be.

Having a working theory will provide some structure to how you’re trying to debug and fix your broken code. However, you need to be able to drop that working theory and look for a new one as soon as you get feedback to the contrary. Several of the longest debugging sessions I’ve undergone were prolonged by me refusing to give up on my initial explanation for what was wrong.

I was joking online the other day that Extreme Programming was the fount of all knowledge about software development. One of the ideas I learned from XP was that having to frequently use a Debugger tool meant that you should be adding more finer-grained automated tests and that you generally don’t want to spend a long time fussing with a Debugger if you can help it.

Pay Attention to Trends and Correlation

“Correlation isn’t Causation” necessarily, but it will absolutely suggest issues with certain types of input or configuration and tell you something that deserves further investigation and be an input into creating a viable theory.

Select isn’t Broken

The saying “Select isn’t Broken” comes from the seminal Pragmatic Programmer book that every aspiring developer should read at some point (it’s pretty short). I also like the Coding Horror take on this from years ago.

The gist of this is that it’s far more likely that the source of your problem is in your freshly written code and not in the much more mature tools you may be using. As a .Net developer, I know that it’s far more likely that a bug in my system is much more likely caused by my code than the core CLR code underneath it that’s used by millions of developers.

This isn’t necessarily saying that you’re a bad developer, but it can definitely save you time to assume that the problem is in your code and start from there.

Another way to put this is to always apply…

Occam’s Razor

From Wikipedia’s entry on Occam’s Razor:

Occam’s Razor is a problem-solving principle that, when presented with competing hypothetical answers to a problem, one should select the one that makes the fewest assumptions

This one is simple, look for the most likely explanation for your problem and focus in on that in your testing and debugging. Sorry to say this, but Occam’s Razor is frequently going to point at your code.

I probably shouldn’t tell anybody this, but an easy “tell” that I’m getting annoyed or impatient with somebody that I’m trying to help solve a problem is if I use either the phrase “Occam’s Razor says…” or something to the effect of “Dude, SELECT isn’t broken…”

I wrote that last sentence a decade ago but it’s still completely true today.

Don’t be so quick to blame the weird thing

So here’s the situation, you just got assigned to a project that uses some kind of technology that is completely new to you. Or maybe you pulled down some hotshot OSS library for the first time. Either way, you might find yourself pounding your head on your desk not being able to understand why some piece of code that uses that weird new thing isn’t working.

The common reaction is to blame the weird new thing, but you might just be completely wrong. Even when faced with some kind of novel technology, you still need to check for the normal, banal problems. I’ve fallen prey to this myself several times in the past, only to realize that my code that used the strange new thing was wrong. In particular, I remember feeling pretty stupid when I realized that I had a file path in the code wrong. It wasn’t the strange, new thing, it was just the common kind of mistake that I’ve made and quickly fixed several hundred times before.

Another way to put this is to always blame your code first. I say that based on the fact that it should be easiest and quickest to troubleshoot your own code to eliminate any possible problems there before getting into the strange new thing.

This is closely related to the initial “Believing that you can figure it out” rule, because blaming the “weird thing” allows you to push off all responsibility instead of diving in to try to understand what’s not working.

This section was written a decade ago after an incident where I happened to be in the main office when a developer said in a stand up meeting that he had a “FubuMVC problem.” As the primary author of FubuMVC, I jumped in and said I’d pair with him to try to fix whatever it was. When we sat down, he showed me the exception he was getting, and a quick glance at the inner exception pointed at it being just a run of the mill issue with a collection in his code not being initialized before the code tried to modify it. Easy money. But of course, the next day I popped into their stand up again and he told them that we had fixed the “FubuMVC problem.” Grr.

As the author of many OSS tools meant for other developers, I sometimes get the brunt of this issue. I’ve got some thoughts and lessons learned about better or worse stack trace and exception messages from my time writing tools and frameworks for other developers that I tackle in a later section — but, the main thing I want to tell other developers sometimes is to…

In no small part, Wolverine’s runtime architecture was purposely designed to streamline Exception stack traces compared to how FubuMVC at that time (or ASP.Net Core today for that matter) would add an absurd amount of framework noise to stack traces. I would argue that this is a significant advantage to Wolverine over the middleware strategies of other tools in the .NET space today.

Read the Exception Message Carefully

Yeah, this one is self explanatory. But yet this section is here because oftentimes the most important information you need to pay attention is buried in an inner exception. Or just don’t jump to incorrect conclusions about what the exception message and stack trace is telling you.

And also, the absolutely most important debugging rule. If you jump online and flag me down to help you solve your problem, don’t ever just say “I had an Exception” but instead post the whole damn stack trace (please)!

Just Flat Out Walk Away

Yeah, I’m not kidding. Sometimes if you’re really stuck and you can get away with this, just walk away and go do something else and hopefully recharge. It’s not a perfectly reliable or predictable strategy at all, but your subconscious will frequently throw up the eventual answer — or at least a new theory — at some random time while you’re walking the dog or doing dishes or whatever your daily routines are.

Probably more importantly, just getting some mental rest and coming back with a fresh mind and hopefully ready to entertain new ideas about what’s going wrong and how to solve that is frequently helpful as compared to banging your head on your desk and hoping this time you’ll notice something in the Debugger that tips you off to the problem.

The Secret of Management

As I was wrapping this up, I realized that I recreated this classic episode of News Radio (i.e., one of the greatest sitcoms ever even if it gave us Joe Rogan and RIP Phil Hartman):

As I wrote last week, I finally got on the AI bus and started using Claude Code. One of the things I’ve been doing with that so far is ripping through “chore” tasks that I’ve long wanted to do, but sounded too time consuming. One of those things was converting Wolverine’s own test suite for its Azure Service Bus integration into using the Azure Service Bus Emulator — which turned out to be extremely fortunate timing as the emulator recently gained support for the Azure Service Bus Management API that finally made the emulator usable.

The emulator is already turning out to be very useful for Wolverine development, especially in areas where we needed 3-5 namespaces just to test features like “namespace per tenant” and named broker features inside of Wolverine. A JasperFx client just happened to ask about that this week, so I lazily had Claude build a new section in the Wolverine docs to explain how that’s working for us and how you might use the emulator for your own local testing. Maybe in the next Wolverine (5.17) we’ll add some syntactical sugar to make this a little easier.

In the meantime, here’s how we’re using the emulator for Wolverine testing:

The Azure Service Bus Emulator allows you to run integration tests against a local emulator instance instead of a real Azure Service Bus namespace. This is exactly what Wolverine uses internally for its own test suite.

Docker Compose Setup

The Azure Service Bus Emulator requires a SQL Server backend. Here is a minimal Docker Compose setup:

networks:
  sb-emulator:
services:
  asb-sql:
    image: "mcr.microsoft.com/azure-sql-edge"
    environment:
      - "ACCEPT_EULA=Y"
      - "MSSQL_SA_PASSWORD=Strong_Passw0rd#2025"
    networks:
      sb-emulator:
  asb-emulator:
    image: "mcr.microsoft.com/azure-messaging/servicebus-emulator:latest"
    volumes:
      - ./docker/asb/Config.json:/ServiceBus_Emulator/ConfigFiles/Config.json
    ports:
      - "5673:5672"   # AMQP messaging
      - "5300:5300"   # HTTP management
    environment:
      SQL_SERVER: asb-sql
      MSSQL_SA_PASSWORD: "Strong_Passw0rd#2025"
      ACCEPT_EULA: "Y"
      EMULATOR_HTTP_PORT: 5300
    depends_on:
      - asb-sql
    networks:
      sb-emulator:

TIP

The emulator exposes two ports: the AMQP port (5672) for sending and receiving messages, and an HTTP management port (5300) for queue/topic administration. These must be mapped to different host ports.

Emulator Configuration File

The emulator reads a Config.json file on startup. A minimal configuration that lets Wolverine auto-provision everything it needs:

{
  "UserConfig": {
    "Namespaces": [
      {
        "Name": "sbemulatorns"
      }
    ],
    "Logging": {
      "Type": "File"
    }
  }
}

You can also pre-configure queues and topics in this file if needed:

{
  "UserConfig": {
    "Namespaces": [
      {
        "Name": "sbemulatorns",
        "Queues": [
          {
            "Name": "my-queue",
            "Properties": {
              "MaxDeliveryCount": 3,
              "LockDuration": "PT1M",
              "RequiresSession": false
            }
          }
        ],
        "Topics": [
          {
            "Name": "my-topic",
            "Subscriptions": [
              {
                "Name": "my-subscription",
                "Properties": {
                  "MaxDeliveryCount": 3,
                  "LockDuration": "PT1M"
                }
              }
            ]
          }
        ]
      }
    ],
    "Logging": {
      "Type": "File"
    }
  }
}

Connection Strings

The emulator uses standard Azure Service Bus connection strings with UseDevelopmentEmulator=true:

// AMQP connection for sending/receiving messages
var messagingConnectionString =
    "Endpoint=sb://localhost:5673;SharedAccessKeyName=RootManageSharedAccessKey;SharedAccessKey=SAS_KEY_VALUE;UseDevelopmentEmulator=true;";
// HTTP connection for management operations (creating queues, topics, etc.)
var managementConnectionString =
    "Endpoint=sb://localhost:5300;SharedAccessKeyName=RootManageSharedAccessKey;SharedAccessKey=SAS_KEY_VALUE;UseDevelopmentEmulator=true;";

WARNING

The emulator uses separate ports for messaging (AMQP) and management (HTTP) operations. In production Azure Service Bus, a single connection string handles both, but the emulator requires you to configure these separately.

Configuring Wolverine with the Emulator

The key to using the emulator with Wolverine is setting both the primary connection string (for AMQP messaging) and the ManagementConnectionString (for HTTP administration) on the transport:

var builder = Host.CreateApplicationBuilder();
builder.UseWolverine(opts =>
{
    opts.UseAzureServiceBus(messagingConnectionString)
        .AutoProvision()
        .AutoPurgeOnStartup();
    // Required for the emulator: set the management connection string
    // to the HTTP port since it differs from the AMQP port
    var transport = opts.Transports.GetOrCreate<AzureServiceBusTransport>();
    transport.ManagementConnectionString = managementConnectionString;
    // Configure your queues, topics, etc. as normal
    opts.ListenToAzureServiceBusQueue("my-queue");
    opts.PublishAllMessages().ToAzureServiceBusQueue("my-queue");
});

Creating a Test Helper

Wolverine’s own test suite uses a static helper extension method to standardize emulator configuration across all tests. Here’s the pattern:

public static class AzureServiceBusTesting
{
    // Connection strings pointing at the emulator
    public static readonly string MessagingConnectionString =
        "Endpoint=sb://localhost:5673;SharedAccessKeyName=RootManageSharedAccessKey;SharedAccessKey=SAS_KEY_VALUE;UseDevelopmentEmulator=true;";
    public static readonly string ManagementConnectionString =
        "Endpoint=sb://localhost:5300;SharedAccessKeyName=RootManageSharedAccessKey;SharedAccessKey=SAS_KEY_VALUE;UseDevelopmentEmulator=true;";
    private static bool _cleaned;
    public static AzureServiceBusConfiguration UseAzureServiceBusTesting(
        this WolverineOptions options)
    {
        // Delete all queues and topics on first usage to start clean
        if (!_cleaned)
        {
            _cleaned = true;
            DeleteAllEmulatorObjectsAsync().GetAwaiter().GetResult();
        }
        var config = options.UseAzureServiceBus(MessagingConnectionString);
        var transport = options.Transports.GetOrCreate<AzureServiceBusTransport>();
        transport.ManagementConnectionString = ManagementConnectionString;
        return config.AutoProvision();
    }
    public static async Task DeleteAllEmulatorObjectsAsync()
    {
        var client = new ServiceBusAdministrationClient(ManagementConnectionString);
        await foreach (var topic in client.GetTopicsAsync())
        {
            await client.DeleteTopicAsync(topic.Name);
        }
        await foreach (var queue in client.GetQueuesAsync())
        {
            await client.DeleteQueueAsync(queue.Name);
        }
    }
}

Writing Integration Tests

With the helper in place, integration tests become straightforward:

public class when_sending_messages : IAsyncLifetime
{
    private IHost _host;
    public async Task InitializeAsync()
    {
        _host = await Host.CreateDefaultBuilder()
            .UseWolverine(opts =>
            {
                opts.UseAzureServiceBusTesting()
                    .AutoPurgeOnStartup();
                opts.ListenToAzureServiceBusQueue("send_and_receive");
                opts.PublishMessage<MyMessage>()
                    .ToAzureServiceBusQueue("send_and_receive");
            }).StartAsync();
    }
    public async Task DisposeAsync()
    {
        await _host.StopAsync();
    }
    [Fact]
    public async Task send_and_receive_a_single_message()
    {
        var message = new MyMessage("Hello");
        var session = await _host.TrackActivity()
            .IncludeExternalTransports()
            .Timeout(30.Seconds())
            .SendMessageAndWaitAsync(message);
        session.Received.SingleMessage<MyMessage>()
            .Name.ShouldBe("Hello");
    }
}

TIP

Use .IncludeExternalTransports() on the tracked session so Wolverine waits for messages that travel through Azure Service Bus rather than only tracking in-memory activity.

Disabling Parallel Test Execution

Because the emulator is a shared resource, tests that create and tear down queues or topics can interfere with each other when run in parallel. Wolverine’s own test suite disables parallel execution for its Azure Service Bus tests:

// Add to a file like NoParallelization.cs in your test project
[assembly: CollectionBehavior(CollectionBehavior.CollectionPerAssembly)]

That is an American Polecat (black-footed ferret), our avatar for our newest Critter Stack project.

Mostly for my own sake to collect my own thoughts, I wanted to do a little update on the Critter Stack roadmap as it looks right now. This is an update on Critter Stack Roadmap for 2026 from December. Things have changed a little bit, or really just become more clear. While the rest of the Critter Stack core team has been early adopters of AI tools, I was late to the party, but two weeks into my own adoption of Claude Code, my ambition for the year has hugely expanded and this new update will reflect that.

Also, we’ve delivered an astonishing amount of new functionality in the first six weeks for 2026:

• Marten’s new composite projection capability that is already getting usage. This feature is going to hopefully make it much easier to create denormalized “query model” projections with Marten to support reporting and dashboard screens
• Wolverine got rate limiting middleware support (community built feature)
• Wolverine’s options for transactional middleware, inbox, outbox, and scheduled messaging support grew to include Oracle, MySql, Sqlite, and CosmosDb. Weasel support for Critter Stack style “it just works” migrations were added for Oracle, MySql, and Sqlite as well

Short to Medium Term Roadmap

I think we are headed toward a Marten 9.0 and Wolverine 6.0 release this year, but I think that’s 2nd or even 3rd quarter this year.

CritterWatch

My personal focus (i.e. JasperFx’s) is switching to CritterWatch as of today. We have a verbal agreement with a JasperFx Software client to have a functional CritterWatch MVP in their environment by the end of March 2026, so here we go! More on this soon as I probably do quite a bit of thinking and analysis on how this should function out loud. The MVP scope is still this:

• A visualization and explanation of the configuration of your Critter Stack application
• Performance metrics integration from both Marten and Wolverine
• Event Store monitoring and management of projections and subscriptions
• Wolverine node visualization and monitoring
• Dead Letter Queue querying and management
• Alerting – but I don’t have a huge amount of detail yet. I’m paying close attention to the issues JasperFx clients see in production applications though, and using that to inform what information Critter Watch will surface through its user interface and push notifications

Marten 8.*

I think that Marten 8.* has just about played out and there’s only a handful of new features I’m personally thinking about before we effectively turn the page on Marten 8.*:

1. First Class EF Core Projections. Just the ability to use an EF Core DbContext to write projected data with EF Core. I’ve thought that this would further help Marten users with reporting needs.
2. An ability to tag event streams with user-defined “natural keys”, and efficient mechanisms to use those natural keys in APIs like FetchForWriting() and FetchLatest(). This will be done in conjunction with Wolverine’s “aggregate handler workflow.” This has been occasionally requested and on our roadmap for a couple years, but it moves up now because of some ongoing client work

Add in some ongoing improvements to the new “composite projection” feature and some improvements to the robustness of the Async Daemon subsystem and I think that’s a wrap on Marten 8.

One wild card is that Marten will gain some kind of model for Dynamic Consistency Boundaries (DCB) this year. I’m not sure whether I think that could or should be done in 8.* or wait for 9.0 though. I was initially dubious about DCB because it largely seemed to be a workaround for event store tools that can’t support strong consistency between event streams the way that Marten can. I’ve come around to DCB a little bit more after reviewing some JasperFx client code where they need to do quite a few cross-stream operations and seeing some opportunity to reduce repetitive code. This will be part of an ongoing process of improving the full Critter Stack’s ability to express cross-stream commands and will involve the integration into Wolverine as well.

Wolverine 5.*

Wolverine has exploded in development and functionality over the past three months, but I think that’s mostly played out as well. Looking at the backlog today, it’s mostly small ball refinements here and there. As mentioned before, I think Wolverine will be part of the improvements to cross-stream operations with Marten as well.

Wolverine gets a lot of community contributions though, and that could continue as a major driver of new features.

Introducing Polecat!

After 10 years of people sagely telling us that Marten would be much more popular if only it supported SQL Server, let’s all welcome Polecat to the Critter Stack. Polecat is going to be a SQL Server Backed Event Store and Document Db tool within the greater Critter Stack ecosystem. As you can imagine, Polecat is very much based on Marten with some significant simplifications. Right now the very basic event sourcing capabilities are already in place, but there’s plenty more to do before I’d suggest using it in a production application.

The key facts about its approach so far:

• Supply a robust Event Store functionality using SQL Server as the storage mechanism
• Mimics Marten’s API, and it’s likely some of the public API ends up being standardized between the two tools
• Uses the same JasperFx.Events library for event abstractions and projection or subscription base types
• Uses Weasel.SqlServer for automatic database migrations similar to Marten
• Supports the bigger Critter Stack “stateful resource” model with Weasel to build out schema objects
• Support both conjoined and separate database multi-tenancy
• Projections will be based on the model in JasperFx.Events and supply SingleStreamProjection, MultiStreamProjection, EventProjection, and FlatTableProjection right out of the box
• STJ only for the serialization. No Newtonsoft support this time
• QuickAppend will be the default event appending approach
• Only support .NET 10
• Only support Sql Server 2025 (v17)
• Utilize the new Sql Server JSON type much like Marten uses the PostgreSQL JSONB
• Strictly using source generators instead of the Marten code generation model — but let’s call this an experiment for now that might end up moving to Marten 9.0 later on

I blew a tremendous amount of time in late 2024 and throughout 2025 getting ready to do this work by pulling out much of the guts of Marten Event Sourcing into potentially reusable libraries, and Polecat is the result.

Selfishly, the CritterWatch approach requires its own event sourced persistence, and I’m hoping that Polecat and SQL Server could be used as an alternative to Marten and PostgreSQL for shops that are interested in CritterWatch but don’t today use PostgreSQL.

Marten 9.0 and Wolverine 6.0

There will be major version releases of the two main critters later this year. The main goal of these releases will be all about optimizing the cold start time of the two tools and at least moving closer to true AOT compliance. We’ll be reevaluating the code generation model of both tools as part of this work.

The only other concrete detail we know is that these releases will dump .NET 8.0 support.

Summary

The road map changes all the time based on what issues clients and users are hitting and sometimes because we just have to stop and respond to something Microsoft or other technologies are doing. But at least for this moment, this is what the Critter Stack core team and I are thinking about.