Let’s say that you have the following scenario, you have an object in your hands that is similar to this one:

It holds some unmanaged resources, so you have to dispose it.

However, this is used in the following manner:

What is the problem? This object may be used concurrently. In the past, the frame was never updated, so it was safe to read from it from multiple threads. Now there is a need to update the frame, but that is a problem. Even though only a single thread can update the frame, there may be other threads that hold a reference to it. That is a huge risk, since they’ll access freed memory. At best, we’ll have a crash, more likely it will be a security issue. At this point in time, we cannot modify all the calling sites without incurring a huge cost. The Frame class is coming from a third party and cannot be changed, so what can we do? Not disposing the frame would lead to a memory leak, after all.

Here is a nice trick to add a finalizer to a third party class. Here is how the code works:

The ConditionalWeakTable associates the lifetime of the disposer with the frame, so only where there are no more outstanding references to the frame (guaranteed by the GC), the finalizer will be called and the memory will be freed.

It’s not the best option, but it is a great one if you want to make minimal modifications to the code and get the right behavior out of it.

It’s very common to model your backend API as a set of endpoints that mirror your internal data model. For example, consider a blog engine, which may have:

• GET /users/{id}: retrieves information about a specific user, where {id} is the ID of the user
• GET /users/{id}/posts: retrieves a list of all posts made by a specific user, where {id} is the ID of the user
• POST /users/{id}/posts: creates a new post for a specific user, where {id} is the ID of the user
• GET /posts/{id}/comments: retrieves a list of all comments for a specific post, where {id} is the ID of the post
• POST /posts/{id}/comments: creates a new comment for a specific post, where {id} is the ID of the post

This mirrors the internal structure pretty closely, and it is very likely that you’ll get to an API similar to this if you’ll start writing a blog backend. This represents the usual set of operations very clearly and easily.

The problem is that the blog example is so attractive because it is inherently limited. There isn’t really that much going on in a blog from a data modeling perspective. Let’s consider a restaurant and how its API would look like:

• GET /menu: Retrieves the restaurant's menu
• POST /orders: Creates a new order
• POST /orders/{order_id}/items: Adds items to an existing order
• POST /payments: Allows the customer to pay their bill using a credit card

This looks okay, right?

We sit at a table, grab the menu and start ordering. From REST perspective, we need to take into account that multiple users may add items to the same order concurrently.

That matters, because we may have bundles to take into account. John ordered the salad & juice and Jane the omelet, and Derek just got coffee. But coffee is already included in Jane’s order, so no separate charge for that. Here is what this will look like:

 ┌────┐┌────┐┌─────┐┌──────────────────────┐
 │John││Jane││Derek││POST /orders/234/items│
 └─┬──┘└─┬──┘└──┬──┘└─────┬────────────────┘
   │     │      │         │       
   │    Salad & Juice     │       
   │─────────────────────>│       
   │     │      │         │       
   │     │     Omelet     │       
   │     │───────────────>│       
   │     │      │         │       
   │     │      │ Coffee  │       
   │     │      │────────>│       

The actual record we have in the end, on the other hand, looks like:

• Salad & Juice
• Omelet & Coffee

In this case, we want the concurrent nature of separate requests, since each user will be ordering at the same time, but the end result should be the final tally, not just an aggregation of the separate totals.

In the same sense, how would we handle payments? Can we do that in the same manner?

 ┌────┐┌────┐┌─────┐┌──────────────────┐
 │John││Jane││Derek││POST /payments/234│
 └─┬──┘└─┬──┘└──┬──┘└────────┬─────────┘
   │     │      │            │          
   │     │     $10           │          
   │────────────────────────>│          
   │     │      │            │          
   │     │      │ $10        │          
   │     │──────────────────>│          
   │     │      │            │          
   │     │      │    $10     │          
   │     │      │───────────>│  

In this case, however, we are in a very different state. What happens in this scenario if one of those charges were declined? What happens if they put too much. What happens if there is a concurrent request to add an item to the order while the payment is underway?

When you have separate operations, you have to somehow manage all of that. Maybe a distributed transaction coordinator or by trusting the operator or by dumb luck, for a while. But this is actually an incredibly complex topic. And a lot of that isn’t inherent to the problem itself, but instead about how we modeled the interaction with the server.

Here is the life cycle of an order:

• POST /orders: Creates a new order – returns the new order id
• ** POST /orders/{order_id}/items: Adds / removes items to an existing order
• ** POST /orders/{order_id}/submit: Submits all pending order items to the kitchen
• POST /orders/{order_id}/bill: Close the order, compute the total charge
• POST /payments/{order_id}: Handle the actual payment (or payments)

I have marked with ** the two endpoints that may be called multiple times. Everything else can only be called once.

Consider the transactional behavior around this sort of interaction. Adding / removing items from the order can be done concurrently. But submitting the pending orders to the kitchen is a boundary, a concurrent item addition would either be included (if it happened before the submission) or not (and then it will just be added to the pending items).

We are also not going to make any determination on the offers / options that were selected by the diners until they actually move to the payment portion. Even the payment itself is handled via two interactions. First, we ask to get the bill for the order. This is the point when we’ll compute orders, and figure out what bundles, discounts, etc we have. The result of that call is the final tally. Second, we have the call to actually handle the payment. Note that this is one call, and the idea is that the content of this is going to be something like the following:

{
  "order_id": "789",
  "total": 30.0,
  "payments": [
    {
      "amount": 15.0,
      "payment_method": "credit_card",
      "card_number": "****-****-****-3456",
      "expiration_date": "12/22",
      "cvv": "123"
    },
    { 
        "amount": 10.0, 
        "payment_method": "cash" },
    {
      "amount": 5.0,
      "payment_method": "credit_card",
      "card_number": "****-****-****-5678",
      "expiration_date": "12/23",
      "cvv": "456"
    }
  ]
}

The idea is that by submitting it all at once, we are removing a lot of complexity from the backend. We don’t need to worry about complex interactions, race conditions, etc. We can deal with just the issue of handling the payment, which is complicated enough on its own, no need to borrow trouble.

Consider the case that the second credit card fails the charge. What do we do then? We already charged the previous one, and we don’t want to issue a refund, naturally. The result here is a partial error, meaning that there will be a secondary submission to handle the remainder payment.

From an architectural perspective, it makes the system a lot simpler to deal with, since you have well-defined scopes. I probably made it more complex than I should have, to be honest. We can simply make the entire process serial and forbid actual concurrency throughout the process. If we are dealing with humans, that is easy enough, since the latencies involved are short enough that they won’t be noticed. But I wanted to add the bit about making a part of the process fully concurrent, to deal with the more complex scenarios.

In truth, we haven’t done a big change in the system, we simply restructured the set of calls and the way you interact with the backend. But the end result of that is the amount of code and complexity that you have to juggle for your infrastructure needs are far more lightweight. On real-world systems, that also has the impact of reducing your latencies, because you are aggregating multiple operations and submitting them as a single shot. The backend will also make things easier, because you don’t need complex transaction coordination or distributed locking.

It is a simple change, on its face, but it has profound implications.

Let’s assume that you want to make a remote call to another server. Your code looks something like this:

var response = await httpClient.GetAsync("https://api.myservice.app/v1/create-snap", cancellationTokenSource.Token);

This is simple, and it works, until you realize that you have a problem. By default, this request will time out in 100 seconds. You can set it to a shorter timeout using HttpClient.Timeout property, but that will lead to other problems.

The problem is that internally, inside HttpClient, if you are using a Timeout, it will call CancellationTokenSource.CancelAfter(). That is... what we want to do, no?

Well, in theory, but there is a problem with this approach. Let's sa look at how this actually works, shall we?

It ends up setting up a Timer instance, as you can see in the code. The problem is that this will modify a global value (well, one of them, there are by default N timers in the process, where N is the number of CPUs that you have on the machine.

What that means is that in order to register a timeout, you need to take a look. If you have a high concurrency situation, setting up the timeouts may be incredibly expensive.

Given that the timeout is usually a fixed value, within RavenDB we solved that using a different manner. We set up a set of timers that will go off periodically and then use this instead. We can request a task that will be completed on the next timeout duration. This way, we'll not be contending on the global locks, and we'll have a single value to set when the timeout happens.

The code we use ends up being somewhat more complex:

var sendTask = httpClient.GetAsync("https://api.myservice.app/v1/create-snap", cancellationTokenSource.Token);
var waitTask = TimeoutManager.WaitFor(TimeSpan.FromSeconds(15), cancellationTokenSource.Token);

if (Task.WaitAny(sendTask, waitTask) == 1)
{
        throw new TimeoutException("The request to the service timed out.");
}

Because we aren't spending a lot of time doing setup for a (rare) event, we can complete things a lot faster.

I don't like this approach, to be honest. I would rather have a better system in place, but it is a good workaround for a serious problem when you are dealing with high-performance systems.

You can see how we implemented the TimeoutManager inside RavenDB, the goal was to get roughly the same time frame, but we are absolutely fine with doing roughly the right thing, rather than pay the full cost of doing this exactly as needed. For our scenario, roughly is more than accurate enough.

When I started using GitHub Copilot, I was quite amazed at how good it was. Sessions using ChatGPT can be jaw dropping in terms of the generated content.

The immediate reaction from many people is to consider what the impact of that would be on the humans who currently fill those roles. Surely, if we can get a machine to do the task of a human, we can all benefit (except for the person made redundant, I guess).

I had a long discussion on the topic recently and I think that it is a good topic for a blog post, given the current interest in the subject matter.

The history of replacing manual labor with automated machines goes back as far as you’ll like to stretch it. I wouldn’t go back to the horse & plow, but certain the Luddites and their arguments about the impact of machinery on the populace will sound familiar to anyone today.

The standard answer is that some professions will go away, but new ones will pop up, instead. The classic example is the ice salesman. That used to be a function, a guy on a horse-drawn carriage that would sell you ice to keep your food cold. You can assume that this profession is no longer relevant, of course.

The difference here is that we now have computer programs and AI taking over what was classically thought impossible. You can ask Dall-E or Stable Diffusion for an image and in a few seconds, you’ll have a beautiful render that may actually match what you requested.

You can start writing code with GitHub Copilot and it will predict what you want to do to an extent that is absolutely awe-inspiring.

So what is the role of the human in all of this? If I can ask ChatGPT or Copilot to write me an email validation function, what do I need a developer for?

Here is ChatGPT’s output:

And here is Copilot’s output:

I would rate the MailAddress version better, since I know that you can’t actually manage emails via Regex. I tried to take this further and ask ChatGPT about the Regex, and got:

ChatGPT is confused, and the answer doesn’t make any sort of sense.

Most of the time spent on “research” for this post was waiting for ChatGPT to actually produce a result, but this post isn’t about nitpicking, actually.

The whole premise around “machines will make us redundant” is that the sole role of a developer is taking a low-level requirement such as email validation and producing the code to match.

Writing such low-hanging fruit is not your job. For that matter, a function is not your job. Nor is writing code a significant portion of that. A developer needs to be able to build the system architecture and design the interaction between components and the overall system.

They need to make sure that the system is performant, meet the non-functional requirements, etc. A developer would spend a lot more time reading code than writing it.

Here is a more realistic example of using ChatGPT, asking it to write to a file using a write-ahead log. I am both amazed by the quality of the answer and find myself unable to use even a bit of the code in there. The scary thing is that this code looks correct at a glance. It is wrong, dangerously so, but you’ll need to be a subject matter expert to know that. In this case, this doesn’t meet the requirements, the provided solution has security issues and doesn’t actually work.

On the other hand, I asked it about password hashing and I would give this answer a good mark.

I believe it will get better over time, but the overall context matters. We have a lot of experience in trying to get the secretary to write code. There have been many tools trying to do that, going all the way back to CASE in the 80s.

There used to be a profession called: “computer”, where you could hire a person to compute math for you. Pocket calculators didn’t invalidate them, and Excel didn’t make them redundant. They are now called accountants or data scientists, instead. And use the new tools (admittedly, calling calculators or Excel new feels very strange) to boost up their productivity enormously.

Developing with something like Copilot is a far easier task, since I can usually just tab complete a lot of the routine details. But having a tool to do some part of the job doesn’t mean that there is no work to be done. It means that a developer can speed up the routine bits and get to grips faster / more easily with the other challenges it has, such as figuring out why the system doesn’t do what it needs to, improving existing behavior, etc.

Here is a great way to use ChatGPT as part of your work, ask it to optimize a function. For this scenario, it did a great job. For more complex scenarios? There is too much context to express.

My final conclusion is that this is a really awesome tool to assist you. It can have a massive impact on productivity, especially for people working in an area that they aren’t familiar with. The downside is that sometimes it will generate junk, then again, sometimes real people do that as well.

The next few years are going to be really interesting, since it provides a whole new level of capability for the industry at large, but I don’t think that it would shake the reality on the ground.

A customer reported a scenario where RavenDB was using stupendous amounts of memory. In the orders of tens of GB on a system that didn’t have that much load.

Our first suspicion was that this is an issue with reading the metrics, since RavenDB will try to keep as much of the data in memory, which sometimes leads users to worry. I spoke about this at length in the past.

In this case, that wasn’t the case. We were able to drill down into the exact cause of the memory usage and we found out that RavenDB was using an abnormally high amount of memory. The question was why that was, exactly.

We looked into the common operations on the server, and we found a suspicious query, it looked something like this:

from index 'Sales/Actions'
where endsWith(WorkflowStage, '/Final')

The endsWith query was suspicious, so we looked into that further. In general, endsWith requires us to scan all the unique terms for a particular field, but in most cases, there aren’t that many unique values for a field. In this case, however, that wasn’t the case, here are some of the values for WorkflowStage:

• Workflows/3a1af12a-b5d2-4c96-9348-177ebaacab6c/Step-2
• Workflows/6aacc86c-2f28-4b8b-8dee-1024314d5add/Final

In total, there were about 250 million sales in the database, each one of them with a unique WorflowStage value.

What does this mean, in terms of RavenDB query execution? Well, the fields are indexed, but we need to effectively do:

This isn’t the actual code, but it will show you what is going on.

In other words, in order to process this query, we have to scan (and materialize) all 250 million unique terms for this field. Obviously that is going to consume a lot of memory.

But what is the solution to that? Instead of doing an expensive endsWith query, we can move the computation from the query time to the index time.

In other words, instead of indexing the WorkflowStage field  as is, we’ll extract the information we want from it. The index would have one of those:

IsFinalWorkFlowStage = doc.WorkflowStage.EndsWith(“/Final”),

WorkflowStagePostfix = doc.WorkflowStage.Split(‘/’).Last()

The first one will check whether the value is final or not, while the second just gets the (one of hopefully a few) postfixes for the field. We can then query using equality instead of endsWith, leading to far better performance and greatly reduced memory usage, since we don’t need to materialize any values during the query.

The recording of my webinar showing off the new Sharding feature in RavenDB 6.0 is now live. I’m showcasing the new technology preview of RavenDB 6.0 and we have a nightly build already available for it. I think the webinar was really good, and I’m super excited to discuss all the ins & out of how this works.

Please take a look, and take the software for a spin. We have managed to get sharding down to a simple, obvious and clear process. And we are very much looking for your feedback.

Sometimes, you need to hold on to data that you really don’t want to have access to. A great example may be that your user will provide you with their theme color preference. I’m sure you can appreciate the sensitivity of preferring a light or dark theme when working in the IDE.

At any rate, you find yourself in an interesting situation, you have a piece of data that you don’t want to know about. In other words, the threat model we have to work with is that we protect the data from a malicious administrator. This may seem to be a far-fetched scenario, but just today I was informed that my email was inside the 200M users leak from Twitter. Having an additional safeguard ensures that even if someone manages to lay their hands on your database, there is little that they can do about it.

RavenDB supports Transparent Data Encryption. In other words, the data is encrypted on disk and will only be decrypted while there is an active transaction looking at it. That is a server-side operation, there is a single key (not actually true, but close enough) that is used for all the data in the database. For this scenario, that is not good enough. We need to use a different key for each user. And even if we have all the data and the server’s encryption key, we should still not be able to read the sensitive data.

How can we make this happen? The idea is that we want to encrypt the data on the client, with the client’s own key, that is never sent to the server. What the server is seeing is an encrypted blob, basically. The question is, how can we make it work as easily as possible. Let’s look at the API that we use to get it working:

As you can see, we indicate that the value is encrypted using the Encrypted<T> wrapper. That class is a very simple wrapper, with all the magic actually happening in the assigned JSON converter. Before we’ll look into how that works, allow me to present you with the way this document looks like to RavenDB:

As you can see, we don’t actually store the data as is. Instead, we have an object that stores the encrypted data as well as the authentication tag. The above document was generated from the following code:

The JSON document holds the data we have, but without knowing the key, we do not know what the encrypted value is. The actual encrypted value is composed of three separate (and quite important) fields:

• Tag – the authentication tag that ensures that the value we decrypt is indeed the value that was encrypted
• Data – this is the actual encrypted value. Note that the size of the value is far larger than the value we actually encrypted. We do that to avoid leaking the size of the value.
• Nonce – a value that ensures that even if we encrypt similar values, we won’t end up with an identical output. I talk about this at length here.

Just storing the data in the database is usually not sufficient, mind. Sure, with what we have right now, we can store and read the data back, safe from data leaks on the server side. However, we have another issue, we want to be able to query the data.

In other words, the question is how, without telling the database server what the value is, can we query for matching values? The answer is that we need to provide a value during the query that would match the value we stored. That is typically fairly obvious & easy. But it runs into a problem when we have cryptography. Since we are using a Nonce, it means that each time we’ll encrypt the value, we’ll get a different encrypted value. How can we then query for the value?

The answer to that is something called DAE (deterministic authenticated encryption). Here is how it works: instead of generating the nonce using random values and ensuring that it is never repeated, we’ll go the other way. We’ll generate the nonce in a deterministic manner. By effectively taking a hash of the data we’ll encrypt. That ensures that we’ll get a unique nonce for each unique value we’ll encrypt. And it means that for the same value, we’ll get the same encrypted output, which means that we can then query for that.

Here is an example of how we can use this from RavenDB:

And with that explanation out of the way, let’s see the wiring we need to make this happen. Here is the JsonConverter implementation that makes this possible:

There is quite a lot that is going on here. This is a JsonConverter, which translates the in-memory data to what is actually sent over the wire for RavenDB.

On read, there isn’t much that is going on there, we pull the individual fields from the JSON and pass them to the DeterministicEncryption class, which we’ll look at shortly. We get the plain text back, read the JSON we previously stored, and translate that back into a .NET object.

On write, things are slightly more interesting. We convert the object to a string, and then we write that to an in memory stream. We ensure that the stream is always aligned on 32 bytes boundary (to avoid leaking the size). Without that step, you could distinguish between “Dark” and “Light” theme users simply based on the length of the encrypted value. We pass the data to the DeterministicEncryption class for actual encryption and build the encrypted value. I choose to use a complex object, but we could also put this into a single field just as easily.

With that in place, the last thing to understand is how we perform the actual encryption:

There is actually very little code here, which is pretty great. The first thing to note is that we have GetCurrentKey, which is a delegate you need to provide to find the current key. You can have a global key for the entire application or for the current user, etc. This key isn’t the actual encryption key, however. In the DerivedKeys function, we use the Blake2b algorithm to turn that 32 bytes key into a 64 bytes value. We then split this into two 32 bits keys. The idea is that we separate the domains, we have one key that is used for computing the SIV and another for the actual encryption.

We use HMAC-Blake2b using the SIV key to compute the nonce of the value in a deterministic manner and then perform the actual encryption. For decryption, we go in reverse, but we don’t need to derive a SIV, obviously.

With this in place, we have about 100 lines of code that add the ability to store client-side encrypted values and query them. Pretty neat, even if I say so myself.

Note that we can store the encrypted value inside of RavenDB, which the database have no way of piercing, and retrieve those values back as well as query them for equality. Other querying capabilities, such as range or prefix scans are far more complex and tend to come with security implications that weaken the level guarantees you can provide. 

I posted this code previously:

And asked what it prints. This is actually an infinite loop that will print an endless amount of zeros to the console. The question is why.

The answer is that we are running into two separate features of C# that interact with each other in a surprising way.

The issue is that we are using a nullable iterator here, and accessing the struct using the Value property. The problem is that this is a struct, and using a property will cause it to be copied.

So the way it works, the code actually runs:

And now you can more easily see the temporary copies that are created and how because we are using a value type here, we are using a different instance each time.

Given the following code:

Can you guess what it will do?

Can you explain why?

I love that this snippet is under 20 lines of code, but being able to explain it shows a lot more knowledge about C# than you would expect.

I asked the following question, about code that uses AsyncLocal as well as async calls. Here is the code again:

This code prints False twice, the question is why. I would expect that the AsyncLocal value to remain the same after the call to Start(), since that is obviously the point of AsyncLocal. It turns out that this isn’t the case.

AsyncLocal is good if you are trying to pass a value down to child tasks, but it won’t be applicable to other tasks that are called in the same level. In other words, it works for children, not siblings tasks. This is actually even more surprising in the code above, since we don’t do any awaits in the Start() method.

The question is why? Looking at the documentation, I couldn’t see any reason for that. Digging deeper into the source code, I figured out what is going on.

We can use SharpLab.io to lower the high level C# code to see what is actually going on here, which gives us the following code for the Start() method:

Note that we call to AsyncTaskMethodBuilder.Start() method, which ends up in AsyncMethodBuilderCore.Start(). There we have a bunch of interesting code, in particular, we remember the current thread execution context before we execute user code, here. After the code is done running, we restore it if this is needed, as you can see here.

That looks fine, but why would the execution context change here? It turns out that one of the few places that interact with it is the AsyncValue itself, which ends up in the ExecutionContext.SetLocalValue. The way it works, each time you set an async local, it creates a new layer in the async stack. And when you exit an async call, it will reset the async stack to the place it was before the async call started.

In other words, the local in the name AsyncLocal isn’t a match to ThreadLocal, but is more similar to a local variable, which goes out of scope on function exit.

This isn’t a new thing, and there are workarounds, but it was interesting enough that I decided to dig deep and understand what is actually going on.