Deep in the heart of Corax (RavenDB’s querying engine), everything deals with something called a Posting List. Posting Lists are a way for the engine to say “all of those documents have the term Fast for the field Speed”.  Conceptually, a Posting List is an ordered set of document ids. In this case (and this is important, the ids in question are numeric, not RavenDB’s document id, which is a string).

An interesting problem with Posting Lists is that a term can be unique (such as a GUID) - only a single document will ever have this value. They can have a small set of values (for example, CreationDate, where only the items created on that day will share the same value). Or they can have many values (for example, Status = ‘Shipped’ for Orders).

The reason those details matter is that we can deal with the three (very) different modes in a distinct manner to reduce the cost of storage that Corax uses for Posting Lists. Internally, Corax has the notion of a PostingListId, which is just a 64-bit number. We use the least significant 2 bits to tell us what kind of Posting List this is.

Typical code to consume this looks like this:

while ((read = provider.FillPostingListIds(plIds)) > 0)
{
    for (int i = 0; i < read; i++)
    {
        var postingListId = plIds[i];
        var termType = (TermIdMask)postingListId & TermIdMask.EnsureIsSingleMask;


        switch (termType)
        {
            case TermIdMask.Single:
            {
                // Accumulate the single decoded entry ID into the entryBuffer
                // Flush to bitmap if the buffer is full
                break;
            }


            case TermIdMask.SmallPostingList:
            {
                // Decode inline via FastPForBufferedReader into the entryBuffer
                // Flush to bitmap if the buffer is full
                break;
            }


            case TermIdMask.PostingList:
            {
                // Flush any accumulated entries from the buffer first
                // Iterate through the full large posting list via FillFromPostings
                break;
            }


            default:
                throw new InvalidOperationException($"Unknown TermIdMask type: {termType}");
        }
    }
}

The code here iterates through a list of Posting List ids, handling each one of the options. This is part of handling queries such as: where CreatedAt > $lastQuarter. We have to get all the distinct dates in the range, and for each date, we need to get all the matching documents for it.

The code here is pretty simple, right? It is fairly obvious what it does, but it has a pretty big problem. It processes each one of the Posting Lists manually & separately. There are two problems with this approach:

• We end up doing a lot of branching, based on which Posting List type we are processing.
• We lose the ability to handle the Posting Lists in bulk.

Because we use the lowest two bits to store the type of the Posting List, we can do better. The insight behind the new approach is that (id & EnsureIsSingleMask) naturally yields 0, 1, or 2 — a perfect index into an array of buckets. Instead of a switch statement, we partition the batch in one pass with no per-item branches:

var buckets = new List<long>[3];
while ((read = provider.FillPostingListIds(plIds)) > 0)
{
   for (int i = 0; i < read; i++)
   {
       buckets[(int)(plIds[i] & 0b11)].AddUnsafe(pid);
   }
}

Of course, you’ll note that we aren’t actually processing those, just putting them in buckets. The fact that we are able to split them into groups in a branchless manner is a fun optimization task, but it doesn’t matter as much as the next stage… we can now deal with a list of Posting Lists that are already divided by type.

For example, for the list holding only a single unique value, I can run the following:

var singlesSpan = CollectionMarshal.AsSpan(buckets[0]);
EntryIdEncodings.DecodeAndDiscardFrequency(singlesSpan, singlesSpan.Length);
var singlesLen = Sorting.SortAndRemoveDuplicates(singlesSpan);
bitmap.AddRange(singlesSpan[..singlesLen]);

This is great, because now I can process the entire list using SIMD in a highly efficient manner. But things get better when we look at the other lists. In the case of the small Posting Lists, for example, the ids that I’m reading are not the actual values, but point to where the values actually reside.

This gives me the chance to actually load them from disk in an optimal, batched manner, like so:

var smallsSpan = buckets[1].ToSpan();
EntryIdEncodings.DecodeAndDiscardFrequency(smallsSpan, smallsSpan.Length);
var smallLen = Sorting.SortAndRemoveDuplicates(smallsSpan);
Container.GetAll(llt, smallsSpan[..smallLen], containerItems.ToSpan(), long.MinValue, pageLocator);


for (int i = 0; i < smallLen; i++)
{
   var item = containerItems[i];
   // read the small posting list and deal with it
}

The key here is the Container.GetAll() call, which takes the list of unique Postings List locations and loads them in an optimized manner. In the previous code style, that was actually pretty hard to do. In this manner, it falls naturally from the way we write the code.

There are also advantages to the fact that we run tight loops with the same code, instead of branching for each type. We also ended up with less code overall, which is also nice.

I have run into this post by John Rush, which I found really interesting, mostly because I so vehemently disagree with it. Here are the points that I want to address in John’s thesis:

1. Open Source movement gonna end because AI can rewrite any oss repo into a new code and commercially redistribute it as their own.

2. Companies gonna use AI to generate their none core software as a marketing effort (cloudflare rebuilt nextjs in  a week).

Can AI rewrite an OSS repo into new code? Let’s dig into this a little bit.

AI models today do a great job of translating code from one language to another. We have good testimonies that this is actually a pretty useful scenario, such as the recent translation of the Ladybird JS engine to Rust.

At RavenDB, we have been using that to manage our client APIs (written in multiple languages & platforms). It has been a great help with that.

But that is fundamentally the same as the Java to C# converter that shipped with Visual Studio 2005. That is 2005, not 2025, mind you. The link above is to the Wayback Machine because the original link itself is lost to history.

AI models do a much better job here, but they aren’t bringing something new to the table in this context.

Claude C Compiler

Now, let’s talk about using the model to replicate a project from scratch. And here we have a bunch of examples. There is the Claude C Compiler, an impressive feat of engineering that can compile the Linux kernel.

Except… it is a proof of concept that you wouldn’t want to use. It produces code that is significantly slower than GCC, and its output is not something that you can trust. And it is not in a shape to be a long-term project that you would maintain over the years.

For a young project, being slower than the best-of-breed alternative is not a bad thing. You’ve shown that your project works; now you can work on optimization.

For an AI project, on the other hand, you are in a pretty bad place. The key here is in terms of long-term maintainability. There is a great breakdown of the Claude C Compiler from the creator of Clang that I highly recommend reading.

The amount of work it would require to turn it into actual production-level code is enormous. I think that it would be fair to say that the overall cost of building a production-level compiler with AI would be in the same ballpark as writing one directly.

Many of the issues in the Claude C Compiler are not bugs that you can “just fix”. They are deep architectural issues that require a very different approach.

Leaving that aside, let’s talk about the actual use case. The Linux kernel’s relationship with its compiler is not a trivial one. Compiler bugs and behaviors are routine issues that developers run into and need to work on.

See the occasional “discussion” on undefined behavior optimizations by the compiler for surprisingly straightforward code.

Cloudflare’s vinext

So Cloudflare rebuilt Next.js in a week using AI. That is pretty impressive, but that is also a lie. They might have done some work in a week, but that isn’t something that is ready. Cloudflare is directly calling this highly experimental (very rightly so).

They also have several customers using it in production already. That is awesome news, except that within literal days of this announcement, multiple critical vulnerabilities have been found in this project.

A new project having vulnerabilities is not unexpected. But some of those vulnerabilities were literal copies of (fixed) vulnerabilities in the original Next.js project.

The issue here is the pace of change and the impact. If it takes an agent a week to build a project and then you throw that into production, how much real testing has been done on it? How much is that code worth?

John stated that this vinext project for Cloudflare was a marketing effort. I have to note that they had to pay bug bounties as a result and exposed their customers to higher levels of risk. I don’t consider that a plus. There is also now the ongoing maintenance cost to deal with, of course.

The key here is that a line of code is not something that you look at in isolation. You need to look at its totality. Its history, usage, provenance, etc. A line of code in a project that has been battle-tested in production is far more valuable than a freshly generated one.

I’ll refer again to the awesome “Things You Should Never Do” from Spolsky. That is over 25 years old and is still excellent advice, even in the age of AI-generated code.

NanoClaw’s approach

You’ve probably heard about the Clawdbot ⇒ Moltbot ⇒ OpenClaw, a way to plug AI directly into everything and give your CISO a heart attack. That is an interesting story, but from a technical perspective, I want to focus on what it does.

A key part of what made OpenClaw successful was the number of integrations it has. You can connect it to Telegram, WhatsApp, Discord, and more. You can plug it into your Gmail, Notes, GitHub, etc.

It has about half a million lines of code (TypeScript), which were mostly generated by AI as well.

To contrast that, we have NanoClaw with ~500 lines of code. Not a typo, it is roughly a thousand times smaller than OpenClaw. The key difference between these two projects is that NanoClaw rebuilds itself on the fly.

If you want to integrate with Telegram, for example, NanoClaw will use the AI model to add the Telegram integration. In this case, it will use pre-existing code and use the model as a weird plugin system. But it also has the ability to generate new code for integrations it doesn’t already have. See here for more details.

On the one hand, that is a pretty neat way to reduce the overall code in the project. On the other hand, it means that each user of NanoClaw will have their own bespoke system.

Contrasting the OpenClaw and NanoClaw approaches, we have an interesting problem. Both of those systems are primarily built with AI, but NanoClaw is likely going to show a lot more variance in what is actually running on your system.

For example, if I want to use Signal as a communication channel, OpenClaw has that built in. You can integrate Signal into NanoClaw as well, but it will generate code (using the model) for this integration separately for each user who needs it.

A bespoke solution for each user may sound like a nice idea, but it just means that each NanoClaw is its own special snowflake. Just thinking about supporting something like that across many users gives me the shivers.

For example, OpenClaw had an agent takeover vulnerability (reported literally yesterday) that would allow a simple website visit to completely own the agent (with all that this implies). OpenClaw’s design means that it can be fixed in a single location.

NanoClaw’s design, on the other hand, means that for each user, there is a slightly different implementation, which may or may not be vulnerable. And there is no really good way to actually fix this.

Summary

The idea that you can just throw AI at a problem and have it generate code that you can then deploy to production is an attractive one. It is also by no means a new one.

The notion of CASE tools used to be the way to go about it. The book Application Development Without Programmers was published in 1982, for example. The world has changed since then, but we are still trying to get rid of programmers.

Generating code quickly is easy these days, but that just shifts the burden. The cost of verifying code has become a lot more pronounced. Note that I didn’t say expensive. It used to be the case that writing the code and verifying it were almost the same task. You wrote the code and thus had a human verifying that it made sense. Then there are the other review steps in a proper software lifecycle.

When we can drop 15,000 lines of code in a few minutes of prompting, the entire story changes. The value of a line of code on its own approaches zero. The value of a reviewed line of code, on the other hand, hasn’t changed.

A line of code from a battle-tested, mature project is infinitely more valuable than a newly generated one, regardless of how quickly it was produced. The cost of generating code approaches zero, sure.

But newly generated code isn’t useful. In order for me to actually make use of that, I need to verify it and ensure that I can trust it. More importantly, I need to know that I can build on top of it.

I don’t see a lot of people paying attention to the concept of long-term maintainability for projects. But that is key. Otherwise, you are signing up upfront to be a legacy system that no one understands or can properly operate.

Production-grade software isn’t a prompt away, I’m afraid to say. There are still all the other hurdles that you have to go through to actually mature a project to be able to go all the way to production and evolve over time without exploding costs & complexities.

Modern coding agents can generate a lot of code very quickly.What once consumed days or weeks of a person’s time is now a simple matter of a prompt and a coffee break.The question is whether this changes any of the fundamental principles ofsoftware development.

A significant portion of software engineering (beyond pure algorithms and data structure work) is not about the code itself, but about managing the social aspects of building and evolving the software over time.

Our system's architecture inherently mirrors the structure of the organization that builds it, as stated by Conway's Law.Therefore, software engineering deals a lot with how a software project is structured to ensure that a (human) team can deliver, make changes, and maintain it over time.

That is why maintainability is such a high-value target: an unmaintainable project quickly becomes one no one can safely change. A good example is OpenSSL circa Heartbleed, or your bank’s COBOL-based core systems.

Does this still apply in the era of coding agents?If a new feature is needed, and I can simply ask a model to regenerate the whole thing from scratch, bypassing technical debt and re-incorporating all constraints, do I still need to worry about maintainability?

My answer in this regard is emphatically yes.There is immense value in ensuring the maintainability of projects, even in the age of AI agents.

One of the most obvious answers is that a maintainable project minimizes the amount of code you must review and touch to make a change.Translating this into the language of Large Language Models, this means you are fundamentally reducing the required context needed to execute a change.

It isn’t just about saving our token budget. Even assuming an essentially unlimited budget, the true value extends beyond mere computation cost.

The maintainability of a software project remains critical because you cannot trust a model to act with absolute competence.You do not have the option of simply telling a model, "Make this application secure," and blindly expecting a perfect outcome. It will give you a thumbs-up and place your product API key in the client-side code.

Furthermore, in a mature software project, even one built entirely with AI, making substantial changes using an AI agent is incredibly risky.Consider the scenario where you spend a week with an agent, carefully tweaking the system's behavior, reviewing the code, and directing its output into the exact shape required.

Six months later, you return to the same area for a change.If the model rewrites everything from scratch, because it can, the entire context and history of those days and weeks of careful guidancewill be lost.This lost context is far more valuable than the code itself.

Remember Hyrum’s Law: "With a sufficient number of users of an API, it does not matter what you promise in the contract:all observable behaviors of your system will be depended on by somebody."

The "sufficient number of users" is surprisingly low, and observable behaviors include non-obvious factors like performance characteristics, the order of elements in a JSON document, the packet merging algorithm in a router you weren’t even aware existed, etc.

The key is this: if a coding agent routinely rewrites large swaths of code, you are not performing an equivalent exchange.

Even if the old code had been AI-generated, it was subsequently subjected to human review, clarification, testing, and verification by users, then deployed - and it survived the production environment and production loads.

The entirely new code has no validated quality yet.You must still expend time and effort to verify its correctness.That is the difference between the existing code and the new one.

Over 25 years ago, Joel Spolsky wrote Things You Should Never Do about the Netscape rewrite. That particular article has withstood the test of time very well. And it is entirely relevant in the age of coding agents as well.

Part of my job involves reviewing code on a project that is over fifteen years old with over a million lines of code. The past week,I've reviewed pull requests ranging from changes of a few hundred lines to one that changed over 10,000 lines of code.

The complexity involved in code review scales exponentially with the amount of code changed, because you must understand not just the changed code, but all its interactions with the rest of the system.

That 10,000+ lines of code pull request is something that is applicable for major features, worth the time and effort that it takes to properly understand and evaluate the change.

Thinking that you can just have a coding agent throw big changes on a project fundamentally misunderstands how projects thrive. And assuming you can have one agent write the code and another review it is a short trip to madness.

In summary, maintainability in the age of coding agents looks remarkably like it did before.The essential requirements remain: clear boundaries, a consistent architecture, and the ability to go into a piece of code and understand exactly what it's doing.

Funnily enough, the same aspects of good software engineering discipline also translate well into best practices for AI usage: limiting the scope of change, reducing the amount of required context, etc.

You should aim to modify a single piece of code, or better yet, create new code instead of modifying existing, validated code (Open/Closed Principle).

Even with AI, the human act of reviewing code is still crucial.And if your proposed solution is to have one AI agent review another, you have simply pushed the problem one layer up, as you are still faced with the necessity of specifying exactly what the system is supposed to be doing in a way that is unambiguous and clear.

There is already a proper way to do that, we call it coding 🙂.

A really interesting problem for developers building agentic systems is moving away from chatting with the AI model. For example, consider the following conversation:

This is a pretty simple scenario where we need to actually step out of the chat and do something else. This seems like an obvious request, right? But it turns out to be a bit complex to build.

The reason for that is simple. AI models don’t actually behave like you would expect them to if your usage is primarily as a chat interface. Here is a typical invocation of a model in code:

class MessageTuple(NamedTuple):
    role: str
    content: str


def call_model(
    message_history: List[MessageTuple],
    tools: List[Callable] = None
):
   pass # redacted

In other words, it is the responsibility of the caller to keep track of the conversation and send the entire conversation to the agent on each round. Here is what this looks like in code:

conversation_history = [
    {
        "role": "user",
        "content": "When do I get my anniversary gift?"
    },
    {
        "role": "agent",
        "content": "Based on our records, your two-year anniversary is in three days. This milestone means you're eligible for a gift card as part of our company's recognition program.\nOur policy awards a $100 gift card for each year of service. Since you've completed two years, a $200 gift card will be sent to you via SMS on October 1, 2025."
    },
    {
        "role": "user",
        "content": "Remind me to double check I got that in a week"
    }
]

Let’s assume that we have a tool call for setting up reminders for users. In RavenDB, this looks like the screenshot below (more on agentic actions in RavenDB here):

And in the backend, we have the following code:

conversation.Handle<CreateReminderArgs>("CreateReminder", async (args) =>
{
    using var session = _documentStore.OpenAsyncSession();
    var at = DateTime.Parse(args.at);
    var reminder = new Reminder
    {
        EmployeeId = request.EmployeeId,
        ConversationId = conversation.Id,
        Message = args.msg,
    };
    await session.StoreAsync(reminder);
    session.Advanced.GetMetadataFor(reminder)["@refresh"] = at;
    await session.SaveChangesAsync();


    return $"Reminder set for {at} {reminder.Id}";
});

This code uses several of RavenDB’s features to perform its task. First we have the conversation handler, which is the backend handling for the tool call we just saw. Next we have the use of the @refresh feature of RavenDB. I recently posted about how you can use this feature for scheduling.

In short, we set up a RavenDB Subscription Task to be called when those reminders should be raised. Here is what the subscription looks like:

from Reminders as r
where r.'@metadata'.'@refresh' != null

And here is the client code to actually handle it:

async Task HandleReminder(Reminder reminder)
{
        var conversation = _documentStore.AI.Conversation(
                agentId: "smartest-agent",
                reminder.ConversationId,
                creationOptions: null
       );
     conversation.AddArtificialActionWithResponse(
"GetRaisedReminders", reminder);
     var result = await conversation.RunAsync();
     await MessageUser(conversation, result);
}

The question now is, what should we do with the reminder?

Going back to the top of this post, we know that we need to add the reminder to the conversation. The problem is that this isn’t part of the actual model of the conversation. This is neither a user prompt nor a model answer. How do we deal with this?

We use a really elegant approach here: we inject an artificial tool call into the conversation history. This makes the model think that it checked for reminders and received one in return, even though this happened outside the chat. This lets the agent respond naturally, as if the reminder were part of the ongoing conversation, preserving the full context.

Finally, since we’re not actively chatting with the user at this point, we need to send a message prompting them to check back on the conversation with the model.

Summary

This is a high-level post, meant specifically to give you some ideas about how you can take your agentic systems to a higher level than a simple chat with the model. The reminder example is a pretty straightforward example, but a truly powerful one. It transforms a simple chat into a much more complex interaction model with the AI.

RavenDB’s unique approach of "inserting" a tool call back into the conversation history effectively tells the AI model, "I've checked for reminders and found a reminder for this user." This allows the agent to handle the reminder within the context of the original conversation, rather than initiating a new one. It also allows the agent to maintain a single, coherent conversational thread with the user, even when the system needs to perform background tasks and re-engage with them later.

You can also use the same infrastructure to create a new conversation, if that makes sense in your domain, and use the previous conversation as “background material”, so to speak. There is a wide variety of options available to fit your exact scenario.

I ran into this tweet from about a month ago:

dax @thdxr

programmers have a dumb chip on their shoulder that makes them try and emulate traditional engineering there is zero physical cost to iteration in software - can delete and start over, can live patch our approach should look a lot different than people who build bridges

I have to say that I would strongly disagree with this statement. Using the building example, it is obvious that moving a window in an already built house is expensive. Obviously, it is going to be cheaper to move this window during the planning phase.

The answer is that it may be cheaper, but it won’t necessarily be cheap. Let’s say that I want to move the window by 50 cm to the right. Would it be up to code? Is there any wiring that needs to be moved? Do I need to consider the placement of the air conditioning unit? What about the emergency escape? Any structural impact?

This is when we are at the blueprint stage - the equivalent of editing code on screen. And it is obvious that such changes can be really expensive. Similarly, in software, every modification demands a careful assessment of the existing system, long-term maintenance, compatibility with other components, and user expectations.This intricate balancing act is at the core of the engineering discipline.

A civil engineer designing a bridge faces tangible constraints: the physical world, regulations, budget limitations, and environmental factors like wind, weather, and earthquakes.While software designers might not grapple with physical forces, they contend with equally critical elements such as disk usage, data distribution, rules & regulations, system usability, operational procedures, and the impact of expected future changes.

Evolving an existing software system presents a substantial engineering challenge.Making significant modifications without causing the system to collapse requires careful planning and execution.The notion that one can simply "start over" or "live deploy" changes is incredibly risky.History is replete with examples of major worldwide outages stemming from seemingly simple configuration changes.A notable instance is the Google outage of June 2025, where a simple missing null check brought down significant portions of GCP. Even small alterations can have cascading and catastrophic effects.

I’m currently working on a codebase whose age is near the legal drinking age. It also has close to 1.5 million lines of code and a big team operating on it. Being able to successfully run, maintain, and extend that over time requires discipline.

In such a project, you face issues such as different versions of the software deployed in the field, backward compatibility concerns, etc. For example, I may have a better idea of how to structure the data to make a particular scenario more efficient. That would require updating the on-disk data, which is a 100% engineering challenge. We have to take into consideration physical constraints (updating a multi-TB dataset without downtime is a tough challenge).

The moment you are actually deployed, you have so many additional concerns to deal with. A good example of this may be that users are used to stuff working in a certain way. But even for software that hasn’t been deployed to production yet, the cost of change is high.

Consider the effort associated with this update to a JobApplication class:

This looks like a simple change, right? It just requires that you (partial list):

• Set up database migration for the new shape of the data.
• Migrate the existing data to the new format.
• Update any indexes and queries on the position.
• Update any endpoints and decide how to deal with backward compatibility.
• Create a new user interface to match this whenever we create/edit/view the job application.
• Consider any existing workflows that inherently assume that a job application is for a single position.
• Can you be partially rejected? What is your status if you interviewed for one position but received an offer for another?
• How does this affect the reports & dashboard?

This is a simple change, no? Just a few characters on the screen. No physical cost. But it is also a full-blown Epic Task for the project - even if we aren’t in production, have no data to migrate, or integrations to deal with.

Software engineersoperate under constraints similar to other engineers, including severe consequences for mistakes (global system failure because of a missing null check). Making changes to large, established codebases presents a significant hurdle.

The moment that you need to consider more than a single factor, whether in your code or in a bridge blueprint, there is a pretty high cost to iterations. Going back to the bridge example, the architect may have a rough idea (is it going to be a Roman-style arch bridge or a suspension bridge) and have a lot of freedom to play with various options at the start. But the moment you begin to nail things down and fill in the details, the cost of change escalates quickly.

Finally, just to be clear, I don’t think that the cost of changing software is equivalent to changing a bridge after it was built. I simply very strongly disagree that there is zero cost (or indeed, even low cost) to changing software once you are past the “rough draft” stage.

We got an interesting use case from a customer - they need to verify that documents in RavenDB have not been modified by any external party, including users with administrator credentials for the database.

This is known as the Rogue Root problem, where you have to protect yourself from potentially malicious root users. That is not an easy problem - in theory, you can safeguard yourself using various means, for example the whole premise of SELinux is based on that.

I don’t really like that approach, since I assume that if a user has (valid) root access, they also likely have physical access. In other words, they can change the operating system to bypass any hurdles in the way.

Luckily, the scenario we were presented with involved detecting changes made by an administrator, which is significantly easier. And we can also use some cryptography tools to help us handle even the case of detecting malicious tampering.

First, I’m going to show how to make this work with RavenDB, then we’ll discuss the implications of this approach for the overall security of the system.

The implementation

The RavenDB client API allows you to hook into the saving process of documents, as you can see in the code below. In this example, I’m using a user-specific ECDsa key (by calling the GetSigningKeyForUser() method).

store.OnBeforeStore += (sender, e) =>
{
    using var obj = e.Session.JsonConverter.ToBlittable(e.Entity, null);
    var date = DateTime.UtcNow.ToString("O");
    var data = Encoding.UTF8.GetBytes( e.DocumentId + date + obj);
    
    using ECDsa key = GetSigningKeyForUser(CurrentUser);
    var signData = key.SignData(data, HashAlgorithmName.SHA256);


    e.DocumentMetadata["DigitalSignature"] = new Dictionary<string, string>
    {
        ["User"] = CurrentUser,
        ["Signature"] = Convert.ToBase64String(signData),
        ["Date"] = date,
        ["PublicKey"] = key.ExportSubjectPublicKeyInfoPem()
    };
};

What you can see here is that we are using the user’s key to generate a signature that is composed of:

• The document’s ID.
• The current signature time.
• The JSON content of the entity.

After we generate the signature, we add it to the document’s metadata. This allows us to verify that the entity is indeed valid and was signed by the proper user.

To validate this afterward, we use the following code:

bool ValidateEntity<T>(IAsyncDocumentSession session,T entity)
{
    var metadata = session.Advanced.GetMetadataFor(entity);
    var documentId = session.Advanced.GetDocumentId(entity);
    var digitalSignature = metadata.GetObject("DigitalSignature") ??
          throw new IOException("Signature is missing for " + documentId);
    var date = digitalSignature.GetString("Date");
    var user = digitalSignature.GetString("User");
    var signature = digitalSignature.GetString("Signature");
    using var key = GetPublicKeyForUser(user);
    using var obj = session.Advanced.JsonConverter.ToBlittable(entity, null);
    var data = Encoding.UTF8.GetBytes(documentId + date + obj);
    var bytes = Convert.FromBase64String(signature);
    return key.VerifyData(data, bytes, HashAlgorithmName.SHA256);
}

Note that here, too, we are using the GetPublicKeyForUser() to get the proper public key to validate the signature. We use the specified user from the metadata to get the key, and we verify the signature against the document ID, the date in the metadata, and the JSON of the entity.

We are also saving the public key of the signing user in the metadata. But we haven’t used it so far, why are we doing this?

The reason we use GetPublicKeyForUser() in the ValidateEntity() call is pretty simple: we want to get the user’s key from the same source. This assumes that the user’s key is stored in a safe location (a secure vault or a hardware key like YubiKey, etc.).

The reason we want to store the public key in the metadata is so we can verify the data on the server side. I created the following index:

from c in docs.Companies
let unverified = Crypto.Verify(c)
where unverified is not null
select new 
{ 
    Problem = unverified
}

I’m using RavenDB’s additional sources feature to add the following code to the index. This exposes the Crypto.Verify() call to the index, and the code uses the public key in the metadata (as well as the other information there) to verify that the document signature is valid.

The index code above will filter all the documents whose signature is valid, so you can easily get all the problematic documents. In other words, it is a quick way of saying: “Find me all the documents whose verification failed”. For compliance, that is quite important and usually requires going over the entire dataset to answer it.

The implications

Let’s consider the impact of such a system. We now have cryptographic verification that the document was modified by a specific user. Any tampering with the document will invalidate the digital signature (or require signing it with your key).

Combine that with RavenDB’s revisions, and you have an immutable log that you can verify using modern cryptography. No, it isn’t a blockchain, but it will put a significant roadblock in the path of anyone trying to just modify the data.

The fact that we do the signing on the client side, rather than the server, means that the server never actually has access to the signing keys (only the public keys). The server’s administrator, in the same manner, doesn’t have a way to get those signing keys and forge a document.

In other words, we solved the Rogue Root problem, and we ensured that a user cannot repudiate a document they signed. It is easy to audit the system for invalid documents (and, combined with revisions, go back to a valid one).

Escape hatch design

If you need this sort of feature for compliance only, you may want to skip the ValidateEntity() call. That would allow an administrator to manually change a document (thus invalidating the digital signature) and still have the rest of the system work. That goes against what we are trying to do, yes, but it is sometimes desirable.

That isn’t required for the normal course of operations, but it can be required for troubleshooting, for example. I’m sure you can think of a number of reasons why it would make things a lot easier to fix if you could just modify the database’s data.

For example, an Order contains a ZipCode with the value "02116" (note the leading zero), which a downstream system turns into the integer 02116. An administrator can change the value to be " 02116", with a leading space, preventing this problem (the downstream system will not convert this to a number, thus keeping the leading 0). Silly, yes - but it happens all the time.

Even though we are invalidating the digital signature, we may want to do that anyway. The index we defined would alert on this, but we can proceed with processing the order, then fix it up later. Or just make a note of this for compliance purposes.

Summary

This post walks you through building a cryptographic solution to protect document integrity within a RavenDB environment, addressing the Rogue Root problem. The core mechanism is a client-side OnBeforeStore hook that generates an ECDsa digital signature for each document. This design ensures that the private keys are never exposed on the server, preventing a database administrator from forging signatures and providing true non-repudiation.

A RavenDB index is used to automatically and asynchronously verify every document's signature against its current content. This index filters for any documents where the digital signature is valid, providing an efficient server-side audit mechanism to find all the documents with invalid signatures.

The really fun part here is that there isn’t really a lot of code or complexity involved, and you get strong cryptographic proof that your data has not been tampered with.

I got a question from one of our users about how they can use RavenDB to manage scheduled tasks. Stuff like: “Send this email next Thursday” or “Cancel this reservation if the user didn’t pay within 30 minutes.”

As you can tell from the context, this is both more straightforward and more complex than the “run this every 2nd Wednesday" you’ll typically encounter when talking about scheduled jobs.

The answer for how to do that in RavenDB is pretty simple, you use the Document Refresh feature. This is a really tiny feature when you consider what it does. Given this document:

{
   "Redacted": "Details",
   "@metdata": {
      "@collection": "RoomAvailabilities",
      "@refresh": "2025-09-14T10:00:00.0000000Z"
   }
}

RavenDB will remove the @refresh metadata field at the specified time. That is all this does, nothing else. That looks like a pretty useless feature, I admit, but there is a point to it.

The act of removing the @refresh field from the document will also (obviously) update the document, which means that everything that reacts to a document update will also react to this.

I wrote about this in the past, but it turns out there are a lot of interesting things you can do with this. For example, consider the following index definition:

from RoomAvailabilitiesas r
where true and not exists(r."@metadata"."@refresh")
select new { 
  r.RoomId,
  r.Date,
  // etc...
}

What you see here is an index that lets me “hide” documents (that were reserved) until that reservation expires.

I can do quite a lot with this feature. For example, use this in RabbitMQ ETL to build automatic delayed sending of documents. Let’s implement a “dead-man switch”, a document will be automatically sent to a RabbitMQ channel if a server doesn’t contact us often enough:

if (this['@metadata']["@refresh"]) 
    return; // no need to send if refresh didn't expire


var alertData = {
    Id: id(this),
    ServerId: this.ServerId,
    LastUpdate: this.Timestamp,
    LastStatus: this.Status || 'ACTIVE'
};


loadToAlertExchange(alertData, 'alert.operations', {
    Id: id(this),
    Type: 'operations.alerts.missing_heartbeat',
    Source: '/operations/server-down/no-heartbeat'
});

The idea is that whenever a server contacts us, we’ll update the @refresh field to the maximum duration we are willing to miss updates from the server. If that time expires, RavenDB will remove the @refresh field, and the RabbitMQ ETL script will send an alert to the RabbitMQ exchange. You’ll note that this is actually reacting to inaction, which is a surprisingly hard thing to actually do, usually.

You’ll notice that, like many things in RavenDB, most features tend to be small and focused. The idea is that they compose well together and let you build the behavior you need with a very low complexity threshold.

The common use case for @refresh is when you use RavenDB Data Subscriptions to process documents. For example, you want to send an email in a week. This is done by writing an EmailToSend document with a @refresh of a week from now and defining a subscription with the following query:

from EmailToSend as e
where true and not exists(e.'@metadata'.'@refresh')

In other words, we simply filter out those that have a @refresh field, it’s that simple. Then, in your code, you can ignore the scheduling aspect entirely. Here is what this looks like:

var subscription = store.Subscriptions
    .GetSubscriptionWorker<EmailToSend>("EmailToSendSubscription");


await subscription.Run(async batch =>
{
    using var session = batch.OpenAsyncSession();
    foreach (var item in batch.Items)
    {
        var email = item.Result;
        await EmailProvider.SendEmailAsync(new EmailMessage
        {
            To = email.To,
            Subject = email.Subject,
            Body = email.Body,
            From = "no-reply@example.com"
        });


        email.Status = "Sent";
        email.SentAt = DateTime.UtcNow;
    }
    await session.SaveChangesAsync();
});

Note that nothing in this code handles scheduling. RavenDB is in charge of sending the documents to the subscription when the time expires.

Using @refresh + Subscriptions in this manner provides us with a number of interesting advantages:

• Missed Triggers: Handles missed schedules seamlessly, resuming on the next subscription run.
• Reliability: Automatically retries subscription processing on errors.
• Rescheduling: When @refresh expires, your subscription worker will get the document and can decide to act or reschedule a check by updating the @refresh field again.
• Robustness: You can rely on RavenDB to keep serving subscriptions even if nodes (both clients & servers) fail.
• Scaleout: You can use concurrent subscriptions to have multiple workers read from the same subscription.

You can take this approach really far, in terms of load, throughput, and complexity. The nice thing about this setup is that you don’t need to glue together cron, a message queue, and worker management. You can let RavenDB handle it all for you.

Tomorrow I’ll be giving a webinar on Building AI Agents in RavenDB. I’m going to show off some really cool ways to apply AI agents on your data, as well as our approach to AI and LLM in general.

I’m looking forward to seeing you there.

Caution: This is going to blow your mind.

AI Agents are all the rage now. The mandate has come: “You must have AI integrated into your systems ASAP.”  What AI doesn’t matter that much, as long as you have it, right?

Today I want to talk about a pretty important aspect of applying AI and AI Agents in your systems, the security problem that is inherent to the issue. If you add an AI Agent into your system, you can bypass it using a “strongly worded letter to the editor”, basically. I wish I were kidding, but take a look at this guide (one of many) for examples.

There are many ways to mitigate this, including using smarter models (they are also more expensive), adding a model-in-the-middle that validates that the first model does the right thing (slower and more expensive), etc.

In this post, I want to talk about a fairly simple approach to avoid the problem in its entirety. Instead of trying to ensure that the model doesn’t do what you don’t want it to do, change the playing field entirely. Make it so it is simply unable to do that at all.

The key here is the observation that you cannot treat AI models as an integral part of your internal systems. They are simply not trustworthy enough to do so. You have to deal with them, but you don’t have to trust them. And that is an important caveat.

Consider the scenario of a defense attorney visiting a defendant in prison. The prison will allow the attorney to meet with the inmate, but it will not trust the attorney to be on their side. In other words, the prison will cooperate, but only in a limited manner.

What does this mean in practice? It means that the AI Agent should not be considered to be part of your system, even if it is something that you built. Instead, it is an external entity (untrusted) that has the same level of access as the user it represents.

For example, in an e-commerce setting, the agent has access to:

• The invoices for the current customer - the customer can already see that, naturally.
• The product catalog for the store - which the customer can also search.

Wait, isn’t that just the same as the website that we already give our users? What is the point of the agent in this case?

The idea is that the agent is able to access this data directly and consume it in its raw form. For example, you may allow it to get all invoices in a date range for a particular customer, or browse through the entire product catalog. Stuff that you’ll generally not make easily available to the user (they don’t make good UX for humans, after all).

In the product catalog example, you may expose the flag IsInInventory to the agent, but not the number of items that you have on hand. We are basically treating the agent as if it were the user, with the same privileges and visibility into your system as the user.

The agent is able to access the data directly, without having to browse through it like a user would, but that is all. For actions, it cannot directly modify anything, but must use your API to act (and thus go through your business rules, validation logic, audit trail, etc).

What is the point in using an agent if they are so limited? Consider the following interaction with the agent:

The model here has access to only the customer’s orders and the ability to add items to the cart. It is still able to do something that is quite meaningful for the customer, without needing any additional rights or visibility.

We should embrace the idea that the agents we build aren’t ours. They are acting on behalf of the users, and they should be treated as such. From a security standpoint, they are the user, after all.

The result of this shift in thinking is that the entire concept of trying to secure the agent from doing something it shouldn’t do is no longer applicable. The agent is acting on behalf of the user, after all, with the same rights and the same level of access & visibility. It is able to do things faster than the user, but that is about it.

If the user bypasses our prompt and convinces the agent that it should access the past orders for their next-door neighbor, it should have the same impact as changing the userId query string parameters in the URL. Not because the agent caught that misdirection, but simply because there is no way for the agent to access any information that the user doesn’t have access to.

Any mess the innovative prompting creates will land directly in the lap of the same user trying to be funny. In other words, the idea is to put the AI Agents on the other side of the security hatch.

Once you have done that, then suddenly a lot of your security concerns become invalid. There is no damage the agent can cause that the user cannot also cause on their own.

It’s simple, it’s effective, and it is the right way to design most agentic systems.

The natural way for developers to test out code is in a simple console application. That is a simple, obvious, and really easy way to test things out. It is also one of those things that can completely mislead you about the actual realities of using a particular API.

For example, let’s take a look at what is probably the most trivial chatbot example:

var kernel = Kernel.CreateBuilder()
    .AddAzureOpenAIChatCompletion(...)
    .Build();


var chatService = kernel.GetRequiredService<IChatCompletionService>();
var chatHistory = new ChatHistory("You are a friendly chatbot.");


while (true)
{
    Console.Write("User: ");
    chatHistory.AddUserMessage(Console.ReadLine());
    var response = await chatService.GetChatMessageContentAsync(
        chatHistory, kernel: kernel);
    Console.WriteLine($"Chatbot: {response}");
    chatHistory.AddAssistantMessage(response.ToString());
}

If you run this code, you’ll be able to have a really interesting chat with the model, and it is pretty amazing that it takes less than 15 lines of code to make it happen.

What is really interesting here is that there is so much going on that you cannot really see. In particular, just how much state is being kept by this code without you actually realizing it.

Let’s look at the same code when we use a web backend for it:

app.MapPost("/chat/{sessionId}", async (string sessionId, 
    HttpContext context, IChatCompletionService chatService,
    ConcurrentDictionary<string, ChatHistory> sessions) =>
{
    var history = sessions.GetOrAdd(sessionId, _ => new ChatHistory(
        "You are a friendly chatbot."));


    var request = await context.Request.ReadFromJsonAsync<UserMessage>();


    history.AddUserMessage(request.Message);


    var response = await chatService.GetChatMessageContentAsync(history,
        kernel: kernel);
    history.AddAssistantMessage(response.ToString());


    return Results.Ok(new { Response = response.ToString() });
});

Suddenly, you can see that you have a lot of state to maintain here. In particular, we have the chat history (which we keep around between requests using a concurrent dictionary). We need that because the model requires us to send all the previous interactions we had in order to maintain context.

Note that for proper use, we’ll also need to deal with concurrency - for example, if two requests happen in the same session at the same time…

But that is still a fairly reasonable thing to do. Now, let’s see a slightly more complex example with tool calls, using the by-now venerable get weather call:

public class WeatherTools
{
    [KernelFunction("get_weather")]
    [Description("Get weather for a city")]
    public string GetWeather(string city) => $"Sunny in {city}.";
}
var builder = Kernel.CreateBuilder().AddAzureOpenAIChatCompletion(...);
builder.Plugins.AddFromType();
var kernel = builder.Build();
var chatService = kernel.GetRequiredService();
var settings = new OpenAIPromptExecutionSettings { 
ToolCallBehavior = ToolCallBehavior.AutoInvokeKernelFunctions 
};
var history = new ChatHistory("You are a friendly chatbot with tools.");
while (true)
{
    Console.Write("User: ");
    history.AddUserMessage(Console.ReadLine());
   var response = await chatService.GetChatMessageContentAsync(
history, settings, kernel);
    history.Add(response);
   Console.WriteLine($"Chatbot: {response.Content}");
}

The AutoInvokeKernelFunctions setting is doing a lot of work for you that isn’t immediately obvious. The catch here is that this is still pretty small & reasonable code. Now, try to imagine that you need a tool call such as: ReplaceProduct(old, new, reason).

The idea is that if we don’t have one type of milk, we can substitute it with another. But that requires user approval for the change. Conceptually, this is exactly the same as the previous tool call, and it is pretty trivial to implement that:

[KernelFunction("replace_product")]
[Description("Confirm product replacement with the user")]
public string ReplaceProduct(string old, string replacement, string reason)
{
    Console.WriteLine($"{old} -> {replacement}: {reason}? (yes/no)");
    return Console.ReadLine();
}

Now, in the same way I transformed the first code sample using the console into a POST request handler, try to imagine what you’ll need to write to send this to the browser for a user to confirm that.

That is when you realize that these 20 lines of code have been transformed into managing a lot of state for you. State that you are implicitly storing inside the execution stack.

You need to gather the tool name, ID and arguments, schlep them to the user, and in a new request get their response. Then you need to identify that this is a tool call answer and go back to the model. That is a separate state from handling a new input from the user.

None of the code is particularly crazy, of course, but you now need to handle the model, the backend, and the frontend states.

When looking at an API, I look to see how it handles actual realistic use cases, because it is so very easy to get caught up with the kind of console app demos - and it turns out that the execution stack can carry quite a lot of weight for you.