Planet Python

Last update: May 22, 2026 04:43 AM UTC

May 22, 2026

Glyph Lefkowitz

Opaque Types in Python

Let’s say you’re writing a Python library.

In this library, you have some collection of state that represents “options” or “configuration” for a bunch of operations. Such a set of options is a bundle of potentially ever-increasing complexity. Thus, you will want it to have an extremely minimal compatibility surface, with a very carefully chosen public interface, that is either small, or perhaps nothing at all. Such an object conveys state and might have some private behavior, but all you want consumers to be able to do is build it in very constrained, specific ways, and then pass it along as a parameter to your own APIs.

By way of example, imagine that you’re wrapping a library that handles shipping physical packages.

There are a zillion ways to do it ship a package. There are different carriers who can ship it for you. There’s air freight, and ground freight, and sea freight. There’s overnight shipping. There’s the option to require a signature. There’s package tracking and certified mail. Suffice it to say, lots of stuff.

If you are starting out to implement such a library, you might need an object called something like ShippingOptions that encapsulates some of this. At the core of your library you might have a function like this:

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async def shipPackage(
        how: ShippingOptions,
        where: Address,
    ) -> ShippingStatus:
    ...

If you are starting out implementing such a library, you know that you’re going to get the initial implementation of ShippingOptions wrong; or, at the very least, if not “wrong”, then “incomplete”. You should not want to commit to an expansive public API with a ton of different attributes until you really understand the problem domain pretty well.

Yet, ShippingOptions is absolutely vital to the rest of your library. You’ll need to construct it and pass it to various methods like estimateShippingCost and shipPackage. So you’re not going to want a ton of complexity and churn as you evolve it to be more complex.

Worse yet, this object has to hold a ton of state. It’s got attributes, maybe even quite complex internal attributes that relate to different shipping services.

Right now, today, you need to add something so you can have “no rush”, “standard” and “expedited” options. You can’t just put off implementing that indefinitely until you can come up with the perfect shape. What to do?

The tool you want here is the opaque data type design pattern. C is lousy with such things (FILE, pthread_*_t, fd_set, etc). A typedef in a header file can easily achieve this.

But in Python, if you expose a dataclass — or any class, really — even if you keep all your fields private, the constructor is still, inherently, public. You can make it raise an exception or something, but your type checker still won’t help your users; it’ll still look like it’s a normal class.

Luckily, Python typing provides a tool for this: typing.NewType.

Let’s review our requirements:

1. We need a type that our client code can use in its type annotations; it needs to be public.
2. They need to be able to consruct it somehow, even if they shouldn’t be able to see its attributes or its internal constructor arguments.
3. To express high-level things (like “ship fast”) that should stay supported as we add more nuanced and complex configurations in the future (like “ship with the fastest possible option provided by the lowest-cost carrier that supports signature verification”).

In order to solve these problems respectively, we will use:

1. a public NewType, which gives us our public name...
2. which wraps a private class with entirely private attributes, to give us an actual data structure, while not exposing the constructor,
3. a set of public constructor functions, which returns our NewType.

When we put that all together, it looks like this:

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from dataclasses import dataclass
from typing import Literal, NewType

@dataclass
class _RealShipOpts:
    _speed: Literal["fast", "normal", "slow"]

ShippingOptions = NewType("ShippingOptions", _RealShipOpts)

def shipFast() -> ShippingOptions:
    return ShippingOptions(_RealShipOpts("fast"))

def shipNormal() -> ShippingOptions:
    return ShippingOptions(_RealShipOpts("normal"))

def shipSlow() -> ShippingOptions:
    return ShippingOptions(_RealShipOpts("slow"))

As a snapshot in time, this is not all that interesting; we could have just exposed _RealShipOpts as a public class and saved ourselves some time. The fact that this exposes a constructor that takes a string is not a big deal for the present moment. For an initial quick and dirty implementation, we can just do checks like if options._speed == "fast" in our shipping and estimation code.

However, the main thing we are doing here is preserving our flexibility to evolve the related APIs into the future, so let’s see how we might do that. For example, let’s allow the shipping options to contain a concrete and specific carrier and freight method:

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from dataclasses import dataclass
from enum import Enum, auto
from typing import NewType

class Carrier(Enum):
    FedEx = auto()
    USPS = auto()
    DHL = auto()
    UPS = auto()

class Conveyance(Enum):
    air = auto()
    truck = auto()
    train = auto()

@dataclass
class _RealShipOpts:
    _carrier: Carrier
    _freight: Conveyance

ShippingOptions = NewType("ShippingOptions", _RealShipOpts)

def shipFast() -> ShippingOptions:
    return ShippingOptions(_RealShipOpts(Carrier.FedEx, Conveyance.air))

def shipNormal() -> ShippingOptions:
    return ShippingOptions(_RealShipOpts(Carrier.UPS, Conveyance.truck))

def shipSlow() -> ShippingOptions:
    return ShippingOptions(_RealShipOpts(Carrier.USPS, Conveyance.train))

def shippingDetailed(
    carrier: Carrier, conveyance: Conveyance
) -> ShippingOptions:
    return ShippingOptions(_RealShipOpts(carrier, conveyance))

As a NewType, our public ShippingOptions type doesn’t have a constructor. Since _RealShipOpts is private, and all its attributes are private, we can completely remove the old versions.

Anything within our shipping library can still access the private variables on ShippingOptions; as a NewType, it’s the same type as its base at runtime, so it presents minimal¹ overhead.

Clients outside our shipping library can still call all of our public constructors: shipFast, shipNormal, and shipSlow all still work with the same (as far as calling code knows) signature and behavior.

If you need to build and convey some state within your public API, while avoiding breakages associated with compatibility churn, hopefully this technique can help you do that!

Acknowledgments

Thanks for reading, and thank you to my patrons who are supporting my writing on this blog. If you like what you’ve read here and you’d like to read more of it, or you’d like to support my various open-source endeavors, you can support my work as a sponsor.

May 22, 2026 12:33 AM UTC

May 21, 2026

The Python Coding Stack

How I Learn (2026 Version) • My Tutor Agent

I know how I like to learn new things. Over the years, I figured out what works for me and what doesn’t. If you read my articles or attend my courses, then you know how I like to learn since I teach in the same way.

The challenge when learning something new is finding resources that are just right for me. And that’s not easy. I know I can learn things better and quicker with resources that fit my style well, but you can’t always find these resources.

I recently got particularly annoyed learning about the biomechanics of sprinting – I do have non-Python interests, yes – because all three textbooks I read, and lots of the online writing in this field, are just, let’s say, not great.

But I now found the solution.

After many decades of learning in the same way, I have now upgraded how I learn thanks to my new tutor, Priya.

Yes, I gave her a name. No, she’s not a real person. Priya is my personalised tutor agent. I’ll tell you all about her below.

And you’ll experience her teaching, too (not on the Python articles, though, I’ll keep writing those the old-fashioned way.) I’ll tell you more about this below, too, but let me first tell you why this works for me.

My Tutor, My Style

I’ve been thinking about the way I learn and teach for many years, from way back when I was a young University lecturer faced with 120 students in a lecture hall. I wasn’t that much older than the students, but I learnt fast. And they liked my teaching (I even have awards to prove it!)

More recently, I’ve been writing a lot. I wrote articles here on The Python Coding Stack and elsewhere. I wrote a Python textbook. I even wrote about learning and technical writing in Breaking the Rules: the substack and the book.

All this meant that I could ask my freshly-spawned agent to spend a bit of time reading what I wrote to understand how I teach, which is how I like to learn. Priya analysed the techniques I use in my writing and understood my motivations for doing what I do through my technical writing texts.

Then, Priya and I had a good chat to refine ideas, to make sure she captured the essence of “my style”.

And since Priya is an AI agent, “my style” became her knowledge base. This knowledge now lives in several lengthy markdown files and is summarised in shorter context packs and an index to ensure Priya’s short-term memory (the context window) isn’t overwhelmed.

Then I was ready to go. Any topic I wanted to learn, large or small, I could ask Priya to research it thoroughly, creating a new set of knowledge files, this time specific to the topic she needed to teach rather than my learning style. And then, she’s ready to teach me.

And it worked. The stuff she prepared was exactly the way I like it.

The Tutor-Student Conversation Course

And here’s the format I settled on (for now). Once the agent completes her research about the topic I want to learn, I ask her to plan a course spanning several modules.

But here’s the refinement loop that makes the real difference:

1. I ask Priya to draft the first module. She writes this in a markdown file.

2. I read through her draft and leave comments and questions directly within the text.

3. Priya reads my questions and revises the text to address my questions. (But read on to find out more about the two categories of comments/questions I leave for her.)

4. Repeat steps 2 and 3 until I feel I understand the topic.

5. Move on to the next module and repeat steps 1 to 4.

This is a human-in-the-loop approach to creating the learning material. Yes, Priya is trained in my way of learning and teaching and in my writing style. But I’m actively having a conversation with her within the text.

This is equivalent to raising your hand in a lesson and asking the teacher a question. A good teacher will then revise how they present the material to address your question.

Priya’s learning materials are just like that. In fact, I will take credit for her output. Sure, I’m not an expert in the subject matter she’s teaching me – that’s the whole point, right? But the output reflects my views and ideas about teaching and includes my questions and queries as I tried to understand and master the topic.

This is a collaboration. Priya and I are co-authors, even though Priya did most of the “writing”.

I tried this approach on several topics, but there are two I want to share with you. I’m setting up two new sections here on The Python Coding Stack, which I’ll use to learn these two topics in public. I’ll publish the “transcripts” of the conversations Priya and I are having. It’s mostly Priya doing the talking, but my questions are there, too.

The first topic I’m learning in public with Priya’s help is Agentic AI. It’s very meta to use agentic AI to learn about agentic AI! I’ll publish an introduction and the first module in the coming days in the new section here on The Python Coding Stack called Agents Unpacked. You can already see this section in the menu on the homepage.

I’ll set up another section to deal with the second topic in a week or so. No spoilers for now except to say it’s directly related to programming but it’s distinct from the articles I publish in the main section on The Python Coding Stack and in The Club.

By the way, you’ll be able to select which sections you want to receive regularly by email. So if you’re interested in my Python core content but not in these other topics, you can pick and choose what to opt out of. You can always go to The Python Coding Stack to read the other sections, of course.

How Priya and I Create These “Courses”

But let me expand on how Priya – my tutor agent – and I created these courses. [Incidentally, those are my em-dashes – I use them often and have always done. Commas would be ambiguous in that context!]

I provide two types of questions or comments to my agent as I read through the drafts: private and public.

Private Questions and Comments

When Priya reads the private questions or comments, she makes changes to the text, but then she deletes my input. So, you won’t see my intervention explicitly in these cases. However, Priya’s text reflects my thoughts. My interventions guide Priya. This type of intervention is similar to an editor’s role, but I’m intervening as a learner more than as an editor.

Public Questions and Comments

However, when Priya comes across a comment or question I mark as public, she leaves it in the text, acknowledges the question, and answers it directly. So, you’ll see my public questions in the text. Priya and I decided not to include too many of these public questions to keep the text flowing. However, I think it’s beneficial to see some of my interventions. My questions may also be your questions.

More Learning. More Articles. More Fun

As with everything to do with AI, this is all very new. It’s a work in progress. I may refine and revise how I interact with my agent. But it’s been fun learning this way, and I hope you enjoy reading my interactions with Priya and you find it useful, too.

To state the obvious, the posts I’ll publish in these two new sections are mostly AI-generated content. If you read this far, then you won’t be surprised by that statement. A year ago, I would never have thought I’d publish anything written by AI. But a year is a long time in the AI world. And this AI content reflects me and my thinking. The agent is my mentee – someone I trained to teach the way I do, to write the way I do. But she’s also my tutor, teaching me new stuff.

So there’s a lot of “me” in what you read, even if it’s mostly written by Priya!

The posts in the main section of The Python Coding Place and those in The Club (for premium subscribers) won’t change. They’re still my writing from beginning to end. Every word and letter you read in those posts is the result of nerve signals going from my brain to my fingers, which tap keys on a keyboard. In this era of AI doing a lot of work for us, I think it’s more important than ever for me to keep using my pre-AI skills. Otherwise, my brain will atrophy, and I don’t want that!

So, in summary, there will soon be four sections here on The Stack:

1. The main area in The Python Coding Stack – no change here, you’ll get the same type of Python articles you’ve been reading for the past 3+ years

2. The Club – the extra Python posts for premium subscribers

3. Agents Unpacked – the Agentic AI course Priya and I are creating for me to learn all about this agentic stuff. Learn with me (and Priya) if you’re interested.

4. Mystery Fourth Section – Stay tuned, you won’t have to wait long. This is also a Priya-Stephen collaboration.

Next post will be the introduction and first section in Agents Unpacked. Soon after, I have another Python post I’m planning for you.

Subscribe now

stephengruppetta.com

Photo by detait

May 21, 2026 09:23 PM UTC

Kevin Renskers

uv is fantastic, but its package management UX is a mess

Astral’s uv has taken the Python world by storm, and for good reason. It is blisteringly fast, handles Python versions with ease, and replaces a half-dozen tools with a single binary. I’ve written multiple articles about it before.

Getting started with a new Python project using uv and adding your first dependencies is very easy. But once you move past the initial setup and into the maintenance phase of a project, i.e. checking for outdated packages and performing routine upgrades, the CLI starts to feel surprisingly clunky compared to its peers like pnpm or Poetry.

Finding outdated packages

In my JavaScript projects, if I want to see what needs an update, I run:

$ pnpm outdated 

This gives a clean, concise list of outdated packages, their current version, the latest version, and the version allowed by your constraints.

In uv, there is no uv outdated. Instead, you have to memorize the following mouthful:

$ uv tree --outdated --depth 1 

The output is also a problem. It doesn’t just show you what is outdated; it shows you your entire top-level dependency tree, with a small annotation next to the ones that have updates available. If you have 50 dependencies and only two are outdated, you still have to scan a 50-line list.

Poetry isn’t much better with its command poetry show --outdated, but at least it only shows actual outdated packages.

Unsafe version constraints by default

This is the most significant philosophical departure uv takes from pnpm and Poetry, and it’s a dangerous one for production stability.

How pnpm/Poetry handle it

When you add a package using pnpm add, it writes it to package.json using the caret requirement (^1.23.4). The caret at the beginning means that any 1.x.x version is allowed, but it will not update to 2.0.0.

Poetry does the same by default, using a format like >=1.23.4,<2.0.0. I find this less readable than ^1.23.4, but the effect is the same.

In both cases, updates are safe by default. You can run pnpm update or poetry update every morning and have high confidence that your build won’t break due to a major API change (assuming the packages you depend on respect SemVer).

How uv handles it

When you run uv add pydantic, it inserts this into your pyproject.toml:

dependencies = [ "pydantic>=2.13.4", ] 

Note the lack of an upper bound. In the eyes of uv, pydantic version 2, 3, and 100 are all perfectly acceptable.

This means uv updates are unsafe by default. If you run a bulk update, you aren’t just getting bug fixes; you are opting into every breaking change published by every maintainer in your dependency graph.

The bad UX of the upgrade command

The commands to actually perform an update in uv feel like they were designed for machines rather than humans.

If you want to update everything in pnpm or Poetry, it’s a simple pnpm update or poetry update command. In uv, you use:

$ uv lock --upgrade 

THOUGHTS

Why isn’t this simply uv update or uv upgrade? Who designed this command line interface? It’s not uv lock --add or uv lock --remove either!

Because of the “no upper bounds” issue mentioned above, uv lock --upgrade is a nuclear option. It will upgrade every single package in your lockfile to their absolute latest versions, ignoring SemVer safety. And this includes deep, nested dependencies you’ve never heard of! Good luck, better hope there are no breaking changes anywhere.

Once you realize this is too risky, you’ll want to upgrade only specific packages. After scouring the subpar output of uv tree --outdated --depth 1 to find them, the syntax becomes a repetitive chore.

How pnpm does it:

$ pnpm update pydantic httpx uvicorn 

How uv does it:

$ uv lock --upgrade-package pydantic --upgrade-package httpx --upgrade-package uvicorn 

Having to repeat the --upgrade-package flag for every single item is a huge hassle when you want to update a bunch of packages. I don’t understand why the UX of uv’s commands is so poor.

There is hope: the bounds flag

Luckily uv has recently introduced a --bounds option for uv add:

$ uv add pydantic --bounds major 

This produces the safer pydantic>=2.13.4,<3.0.0 constraint we’ve come to expect. However, this is currently an opt-in feature. You have to remember to type it every time, and as of now, it is considered a preview feature.

Until --bounds major (or a similar configuration) becomes the default behavior, uv users are essentially forced to choose between two bad options:

1. Manually edit pyproject.toml to add upper bounds for every single dependency.
2. Live in fear that uv lock --upgrade will accidentally pull in a breaking major version change.

What I’d like to see

I love uv. Its speed is transformative, and the way it manages Python toolchains is second to none. But as a package manager, the developer experience for maintaining a project is currently a step backward from the tools that came before it.

We need a dedicated uv outdated command that filters noise, a more ergonomic update command that doesn’t require repeating flags, and default version constraints that respect the sanity of Semantic Versioning.

Until then, I’ll be double-checking every single line of my lockfile changes with a healthy dose of suspicion.

May 21, 2026 06:08 PM UTC

Real Python

Quiz: Context Managers and Using Python's with Statement

In this quiz, you’ll test what you learned in the video course Context Managers and Using Python’s with Statement.

By working through this quiz, you’ll revisit how the with statement runs setup and teardown for you, how to use standard-library context managers like open(), and how to write your own context managers as classes or with the @contextmanager decorator.

[ Improve Your Python With 🐍 Python Tricks 💌 – Get a short & sweet Python Trick delivered to your inbox every couple of days. >> Click here to learn more and see examples ]

May 21, 2026 12:00 PM UTC

PyCharm

Making software accessible often comes down to removing small but repeated points of friction in everyday workflows. Today, on Global Accessibility Awareness Day, we’re sharing recent improvements in JetBrains IDEs across several areas: compatibility with assistive technologies on various platforms, keyboard navigation, and non-visual feedback. Some of these improvements are already available, and some are coming later this year.

You can use the audio player below to listen to this blog post.

Better compatibility with assistive technologies

One of the key areas we’ve been working on is improving how JetBrains IDEs interact with OS-level accessibility tools.

Improved Magnifier support on Windows

Screen magnifiers are among the most commonly used assistive technologies in JetBrains IDEs. Until recently, the built-in Windows Magnifier didn’t reliably follow the text cursor in the editor, making navigation and editing more difficult for low-vision users. We’ve implemented support for cursor tracking so Magnifier follows text as you type, just as it does in other applications.

This builds on earlier work on macOS, where we addressed text cursor tracking with macOS Zoom. Now, the same support is being extended to Windows.

Orca and GNOME Magnifier support on Linux

With version 2026.2, coming this summer, JetBrains IDEs will allow you to use the Orca screen reader and GNOME Magnifier in supported Linux environments. 

This is an active area of work, with multiple related tasks already underway. Accessibility shouldn’t depend on your operating system, and we’re continuing to improve support across platforms.

More predictable keyboard navigation

We’ve also been making it easier to move through the IDE without relying on a mouse.

Main menu access with Alt on Windows

In native Windows applications, pressing Alt moves the focus to the main menu, allowing you to navigate it with the keyboard. This behavior was previously missing from JetBrains IDEs, and screen readers, such as NVDA, would sometimes announce the system menu instead.

Now, the main menu behaves in a way that feels familiar and predictable for keyboard-only and screen-reader users, and the bright focus indicator helps low-vision users identify the selected item.  

Navigating between major parts of the IDE

Another focus area is the experience of moving between different parts of the IDE interface, such as toolbars, panels, and the editor. We’re working on a more structured model for navigating through the big component groups:

• Tab and Shift+Tab move the focus within the current area.
• A dedicated shortcut lets you jump between larger sections of the IDE.

This reduces the effort required to reach essential controls and makes the overall layout easier to navigate. For the current iteration, we made it possible to bring the main toolbar and status bar into focus, and we fixed the Project and Git toolbar widgets, which were not selectable by screen readers, even though other elements already were. 

As the next step, we’ll polish specific controls and include tool window bars on both sides of the IDE frame in the navigation flow.

Exploring richer non-visual feedback with audio cues

Accessibility is not only about reaching controls, but also about understanding what’s happening while you work. We’re exploring ways to provide richer audio feedback in the IDE. Two directions we’re currently investigating:

• Contextual signals when the caret lands on lines with errors, warnings, breakpoints, or version control changes. We want the IDE to provide immediate, non-visual feedback in context.
• More general audio notifications for IDE actions and state changes.

The goal is to reduce the need to rely on visual indicators or switch contexts just to understand what changed. Instead, we want the IDE to provide that information more directly.

Accessibility as an ongoing effort

We’re improving accessibility in JetBrains IDEs across multiple areas at once, including by providing compatibility with assistive technologies like screen readers and magnifiers, as well as by offering more consistent keyboard navigation and clearer feedback for events that are otherwise mostly visual.

These improvements build on earlier updates, such as support for VoiceOver and NVDA, a high-contrast UI theme, and color schemes for red-green vision deficiency. There’s still more to do, and we’ll continue working in this direction.

We’d love to hear from you

We’re eager to hear from developers who rely on accessibility features, as well as from anyone interested in improving the experience of using them.

If you have ideas or feedback about accessibility in JetBrains IDEs, you can reach us directly at accessibility@jetbrains.com. You can also report issues through YouTrack or the support request form.

If you’d like to stay informed about accessibility improvements, you can subscribe to updates here.

May 21, 2026 10:40 AM UTC

Improving Accessibility in JetBrains IDEs: What’s New and What’s Next in 2026

May 21, 2026 06:45 AM UTC

May 20, 2026

Talk Python Blog

Audit Your Python App Like Mozilla Audited Firefox

Earlier this year, Mozilla announced that they had pointed Claude at the Firefox JavaScript runtime. The agent surfaced more than 100 bugs, 14 of them serious enough to become CVEs. That is the kind of result you used to only get from an expensive pen-testing engagement, and even then it would take weeks. Reading that announcement, I kept circling back to one question: could a working Python web developer pull off the same kind of audit on their own app, without a security firm on retainer and without spending pen-testing-firm money? I built a course to answer that, and the short answer is yes.

May 20, 2026 10:02 PM UTC

Paolo Melchiorre

My PyCon US 2026

A timeline of my PyCon US 2026 journey, in Long Beach (US), told through the Mastodon posts I shared along the way.

May 20, 2026 10:00 PM UTC

Kay Hayen

Nuitka Release 4.1

This is to inform you about the new stable release of Nuitka. It is the extremely compatible Python compiler, “download now”.

This release adds many new features and corrections with a focus on async code compatibility, missing generics features, and Python 3.14 compatibility and Python compilation scalability yet again.

Bug Fixes

• Python 3.14: Fix, decorators were breaking when disabling deferred annotations. (Fixed in 4.0.1 already.)

• Fix, nested loops could have wrong traces lead to mis-optimization. (Fixed in 4.0.1 already.)

• Plugins: Fix, run-time check of package configuration was incorrect. (Fixed in 4.0.1 already.)

• Compatibility: Fix, __builtins__ lacked necessary compatibility in compiled functions. (Fixed in 4.0.1 already.)

• Distutils: Fix, incorrect UTF-8 decoding was used for TOML input file parsing. (Fixed in 4.0.1 already.)

• Fix, multiple hard value assignments could cause compile time crashes. (Fixed in 4.0.1 already.)

• Fix, string concatenation was not properly annotating exception exits. (Fixed in 4.0.2 already.)

• Windows: Fix, --verbose-output and --show-modules-output did not work with forward slashes. (Fixed in 4.0.2 already.)

• Python 3.14: Fix, there were various compatibility issues including dictionary watchers and inline values. (Fixed in 4.0.2 already.)

• Python 3.14: Fix, stack pointer initialization to localsplus was incorrect to avoid garbage collection issues. (Fixed in 4.0.2 already.)

• Python 3.12+: Fix, generic type variable scoping in classes was incorrect. (Fixed in 4.0.2 already.)

• Python 3.12+: Fix, there were various issues with function generics. (Fixed in 4.0.2 already.)

• Python 3.8+: Fix, names in named expressions were not mangled. (Fixed in 4.0.2 already.)

• Plugins: Fix, module checksums were not robust against quoting style of module-name entry in YAML configurations. (Fixed in 4.0.2 already.)

• Plugins: Fix, doing imports in queried expressions caused corruption. (Fixed in 4.0.2 already.)

• UI: Fix, support for uv_build in the --project option was broken. (Fixed in 4.0.2 already.)

• Compatibility: Fix, names assigned in assignment expressions were not mangled. (Fixed in 4.0.2 already.)

• Python 3.12+: Fix, there were still various issues with function generics. (Fixed in 4.0.3 already.)

• Clang: Fix, debug mode was disabled for clang generally, but only ClangCL and macOS Clang didn’t want it. (Fixed in 4.0.3 already.)

• Zig: Fix, --windows-console-mode=attach|disable was not working when using Zig. (Fixed in 4.0.3 already.)

• macOS: Fix, yet another way self dependencies can look like, needed to have support added. (Fixed in 4.0.3 already.)

• Python 3.12+: Fix, generic types in classes had bugs with multiple type variables. (Fixed in 4.0.3 already.)

• Scons: Fix, repeated builds were not producing binary identical results. (Fixed in 4.0.3 already.)

• Scons: Fix, compiling with newer Python versions did not fall back to Zig when the developer prompt MSVC was unusable, and error reporting could crash. (Fixed in 4.0.4 already.)

• Zig: Fix, the workaround for Windows console mode attach or disable was incorrectly applied on non-Windows platforms. (Fixed in 4.0.4 already.)

• Standalone: Fix, linking with Python Build Standalone failed because libHacl_Hash_SHA2 was not filtered out unconditionally. (Fixed in 4.0.4 already.)

• Python 3.6+: Fix, exceptions like CancelledError thrown into an async generator awaiting an inner awaitable could be swallowed, causing crashes. (Fixed in 4.0.4 already.)

• Fix, not all ordered set modules accepted generators for update. (Fixed in 4.0.5 already.)

• Plugins: Disabled warning about rebuilding the pytokens extension module. (Fixed in 4.0.5 already.)

• Standalone: Filtered libHacl_Hash_SHA2 from link libs unconditionally. (Fixed in 4.0.5 already.)

• Debugging: Disabled unusable unicode consistency checks for Python versions 3.4 to 3.6. (Fixed in 4.0.5 already.)

• Python3.12+ Avoided cloning call nodes on class level which caused issues with generic functions in combination with decorators. (Added in 4.0.5 already.)

• Python 3.12+: Added support for generic type variables in async def functions. (Added in 4.0.5 already.)

• UI: Fix, flushing outputs for prompts was not working in all cases when progress bars were enabled. (Fixed in 4.0.6 already.)

• UI: Fix, unused variable warnings were missing at C compile time when using zig as a C compiler. (Fixed in 4.0.6 already.)

• Scons: Fix, forced stdout and stderr paths as a feature was broken. (Fixed in 4.0.6 already.)

• Fix, replacing a branch did not accurately track shared active variables causing optimization crashes. (Fixed in 4.0.7 already.)

• macOS: Fix, failed to remove extended attributes because files need to be made writable first. (Fixed in 4.0.7 already.)

• Fix, dict pop and setdefault using with := rewrites lacked exception-exit annotations for un-hashable keys. (Fixed in 4.0.8 already.)

• Python 3.13: Fix, the __parameters__ attribute of generic classes was not working. (Fixed in 4.0.8 already.)

• Python 3.11+: Fix, starred arguments were not working as type variables. (Fixed in 4.0.8 already.)

• Python2: Fix, FileNotFoundError compatibility fallback handling was not working properly. (Fixed in 4.0.8 already.)

• Compatibility: Fix, loop ownership check in value traces was missing, causing issues with nested loops.

• Windows: Improved --windows-console-mode=attach to properly handle console handles, enabling cases like os.system to work nicely.

• Python2: Fix, there was a compatibility issue where providing default values to the mkdtemp function was failing.

• Windows: Fix, there were spurious issues with C23 embedding in 32-bit MinGW64 by switching to coff_obj resource mode for it as well.

• Plugins: Fix, the post-import-code execution could fail because the triggering sub-package was not yet available in sys.modules.

• UI: Fix, listing package DLLs with --list-package-dlls was broken due to recent plugin lifecycle changes.

• UI: Fix, --list-package-exe was not working properly on non-Windows platforms failing to detect executable files correctly.

• UI: Handled paths starting with {PROGRAM_DIR} the same as a relative path when parsing the --onefile-tempdir-spec option.

• Plugins: Followed multiprocessing forkserver changes for newer Python versions.

• Python 3.12+: Fix, generic class type parameters handling was incorrect.

• Python 3.12: Fix, deferred evaluation of type aliases was failing.

• Python 3.12+: Aligned sum built-in float summation with CPython’s compensated sum for better accuracy.

• Python 3.10+: Fix, uncompiled coroutine throw() return handling was incorrect, restoring completed coroutine results via StopIteration.value rather than exposing them as ordinary return values to the outer await chain.

• Python 3.13+: Fix, uncompiled coroutine cancel()/await suspension handling was incorrect, improved to ensure integration compatibility.

• macOS: Made finding create-dmg more robustly by also checking the Homebrew path for Intel and from PATH properly.

• Compatibility: Fix, class frames were not exposing frame locals.

• UI: Detected static-libpython problems, which affected some forms of Anaconda.

• Distutils: Rejected --project mixed with --main arguments as it is not useful.

• macOS: Fix, zig from PATH or from ziglang was not being used.

• Distutils: Fix, the wrong module-root config value was being checked for uv build backend.

• macOS: Fix, was attempting to change removed (rejected) DLLs, which of course failed and errored out.

• Python 3.14: Fix, tuple reuse was not fully compatible, potentially causing crashes due to outdated hash caches.

• Fix, fake modules were still being attempted to located when imported by other code, which could conflict with existing modules.

• Python 3.5+: Fix, failed to send uncompiled coroutines the sent in value in yield from.

• Fix, older gcc compilers lacking newer intrinsic methods had compilation issues that needed to be addressed.

• Standalone: Fix, multiphase module extension modules with post-load code were not working properly.

• Fix, Avoid using the non-inline copy of pkg_resources with the inline copy of Jinja2. These could mismatch and cause errors.

• Fix, loops could make releasing of previous values very unclear, causing optimization errors.

• Fix, incbin resource mode was not working with old gcc C++ fallback.

• Python 3.4 to 3.6: Fix, bytecode demotion was not working properly for these versions, also bytecode only files not working.

• Plugins: Added a check for the broken patchelf versions 0.10 and 0.11 to prevent breaking Qt plugins.

• Android: Allowed patchelf version 0.18 on Android.

• Windows: Fix, the header path for self uninstalled Python was not detected correctly.

• Release: Fix, inclusion of the pkg_resources inline copy for Python 2 to source distributions was missing.

• UI: Detected the OBS versions of SUSE Linux better.

• Suse: Allowed using patchelf 0.18.0 there too.

• Python 3.11: Fix, package and module dicts were not aligned close enough to avoid a CPython bug.

• Fix, unbound compiled methods could crash when called without an object passed.

• Standalone: Fix, multiphase module extension modules with postload. (Fixed in 4.0.8 already.)

• Onefile: Fix, while waiting for the child, it may already be terminated.

• macOS: Removed existing absolute rpaths for Homebrew and MacPorts.

• Python 3.14: Avoided warning in CPython headers.

• Python 3.14: Followed allocator changes more closely.

• Compatibility: Avoided using pkg_resources for Jinja2 template location for loading.

• No-GIL: Applied some bug fixes to get basic things to work.

Package Support

• Standalone: Add support for newer paddle version. (Added in 4.0.1 already.)

• Standalone: Add workaround for refcount checks of pandas. (Fixed in 4.0.1 already.)

• Standalone: Add support for newer h5py version. (Added in 4.0.2 already.)

• Standalone: Add support for newer scipy package. (Added in 4.0.2 already.)

• Plugins: Revert accidental os.getenv over os.environ.get changes in anti-bloat configurations that stopped them from working. Affected packages are networkx, persistent, and tensorflow. (Fixed in 4.0.5 already.)

• Standalone: Added missing DLLs for openvino. (Added in 4.0.7 already.)

• Enhanced the package configuration YAML schema by adding the relative_to parameter for from_filenames DLL specification, avoiding error-prone purely relative paths.

• Standalone: Fix, flet_desktop app assets were missing, now preserving the packaged runtime and sidecar DLLs.

• Standalone: Added support for the tyro package.

• Standalone: Added data files for the perfetto package.

• Standalone: Added support for anyio process forking.

• Standalone: Added support for the plotly.graph package.

• Anaconda: Fix, dependencies for the numpy conda package on Windows were incorrect.

• Plugins: Enhanced the auto-icon hack in PySide6 to use compatible class names.

• Standalone: Fix, Qt libraries were duplicated with PySide6 WebEngine framework support on macOS.

• Plugins: Fix, automatic detection of mypyc runtime dependencies was including all top level modules of the containing package by accident. (Fixed in 4.0.5 already.)

• Anaconda: Fix, delvewheel plugin was not working with Python 3.8+. This enhances compatibility with installed PyPI packages that use it for their DLLs. (Fixed in 4.0.6 already.)

• Plugins: Fix, our protection workaround could confuse methods used with PySide6.

New Features

• UI: Added the --recommended-python-version option to display recommended Python versions for supported, working, or commercial usage.

• UI: Add message to inform users about Nuitka[onefile] if compression is not installed. (Added in 4.0.1 already.)

• UI: Add support for uv_build in the --project option. (Added in 4.0.1 already.)

• Onefile: Allow extra includes as well. (Added in 4.0.2 already.)

• UI: Add nuitka-project-set feature to define project variables, checking for collisions with reserved runtime variables. (Added in 4.0.2 already.)

• Scons: Added new option to select --reproducible builds or not. (Added in 4.0.6 already.)

• Python 3.10+: Added support for importlib.metadata.package_distributions(). (Added in 4.0.8 already.)

• Plugins: Added support for the multiprocessing forkserver context. (Added in 4.0.8 already, for 4.1 Python 3.6 and earlier, as well as 3.14 support were added too.)

• Reports: Added structured resource usage (rusage) performance information to compilation reports.

• Reports: Included individual module-level C compiler caching (ccache/clcache) statistics in compilation reports.

• Added support for detecting and correctly resolving the Python prefix for the PyEnv on Homebrew Python flavor.

• macOS: Added support for rusage information for Scons.

• UI: Added the __compiled__.extension_filename attribute to give the real filename of the containing extension module.

• Windows: Added support for --clang or ARM. (Added in 4.0.8 already.)

• Windows: Added support for resources names as not just integers, important when we copy them from template files.

• MacPorts: Added basic support for this Python flavor. More work will be needed to get it to work fully though.

Optimization

• Avoid including importlib._bootstrap and importlib._bootstrap_external. (Added in 4.0.1 already.)

• Linux: Cached the syscall used for time keeping during compilation to avoid loading libc for each trace. (Added in 4.0.8 already.)

• UI: Output a warning for modules that remain unfinished after the third optimization pass.

• Added an extra micro pass trigger when new variables are introduced or variable usage changes severely, ensuring optimizations are fully propagated, avoiding unnecessary extra full passes.

• Provided scripts to compile Python statically with PGO tailored for Nuitka on Linux, Windows, and macOS.

• Added support for running the Data Composer tool from a compiled Nuitka binary without spawning an uncompiled Python process.

• Enhanced the usage of vectorcall for PyCFunction objects by directly checking for its presence instead of relying purely on flags, allowing more frequent use of this faster execution path.

• Cached frequently used declarations for top-level variables to speed up C code generation.

• Sped up trace collection merging by avoiding unnecessary set creation and using a set instead of a list for escaped traces.

• Optimized plugin hook execution by tracking overloaded methods and added an option to show plugin usage statistics.

• Improved performance of module location by avoiding unnecessary module name reconstruction and redundant filesystem checks for pre-loaded packages.

• Improved the caching of distribution name lookups to effectively avoid repeated IO operations across all package types.

• Plugins: Cached callback plugin dispatch for onFunctionBodyParsing and onClassBodyParsing to skip argument computation when no plugin overrides them.

• Python 3.13: Handled sub-packages of pathlib as hard modules.

• Handled hard attributes through merge traces as well.

• Made constant blobs more compact by avoiding repeated identifiers and unnecessary fields.

• Enhanced Python compilation scripts further. (Fixed in 4.0.8 already.)

• Recognized late incomplete variables better. (Fixed in 4.0.8 already.)

• Made constant blobs more compact. (Fixed in 4.0.8 already.)

• Optimized calls with only constant keywords and variable posargs too.

Anti-Bloat

• Fix, memory bloat occurred when C compiling sqlalchemy. (Fixed in 4.0.2 already.)

• Avoid using pydoc in PySimpleGUI. (Added in 4.0.2 already.)

• Avoided using doctest from zodbpickle. (Added in 4.0.5 already.)

• Avoided inclusion of cython when using pyav. (Added in 4.0.7 already.)

• Avoided including typing_extensions when using numpy. (Added in 4.0.7 already.)

Organizational

• UI: Relocated the warning about the available source code of extension modules to be evaluated at a more appropriate time.

• Debian: Remove recommendation for libfuse2 package as it is no longer useful.

• Debian: Used platformdirs instead of appdirs.

• Debugging: Removed Python 3.11+ restriction for clang-format as it is available everywhere, even Python 2.7, and we still want nicely formatted code when we read things. (Added in 4.0.6 already.)

• Removed no longer useful inline copy of wax_off. We have our own stubs generator project.

• Release: Added missing package to the CI container for building Nuitka Debian packages.

• Developer: Updated AI instructions for creating Minimal Reproducible Examples (MRE) to skip unneeded C compilation.

• Debugging: Added an internal function for checking if a string is a valid Python identifier.

• AI: Added a task in Visual Studio Code to export the currently selected Python interpreter path to a file, making it available as “python” and “pip” matching the selected interpreter. This makes it easier to use a specific version with no instructions needed.

• AI: Updated the rules to instruct AI to only generate useful comments that add context not present in the code.

• Containers: Added template rendering support for Jinja2 (.j2) container files in our internal Podman tools.

• Projects: Clarified the current status and rationale of Python 2.6 support in the developer manual.

• Debugging: Added experimental flag --experimental=ignore-extra-micro-pass to allow ignoring extra micro pass detection.

• Visual Code: Added integration scripts for bash and zsh autocompletion of Nuitka CLI options. These are now also integrated into Visual Studio Code terminal profiles and the Debian package.

• RPM: Included the Python compile script for Linux.

• RPM: Removed the requirement for distutils in the spec.

Tests

• Install only necessary build tools for test cases.

• Avoided spurious failures in reference counting tests due to Python internal caching differences. (Fixed in 4.0.3 already.)

• Fix, the parsing of the compilation report for reflected tests was incorrect.

• Python 3.14: Ignored a syntax error message change.

• Python 3.14: Added test execution support options to the main test runner to use this version as well.

• Fix, the runner binary path was mishandled for the third pass of reflected compilations.

• Removed the usage of obsolete plugins in reflected compilation tests.

• Debugging: Prevented boolean testing of namedtuples to avoid unexpected bugs.

• Added the Test suffix to syntax test files and disabled “python” mode and spell checking for them to resolve issues reported in IDEs.

• Fix, newline handling in diff outputs from the output comparison tool was incorrect.

• Covered post-import-code functionality with a new subpackage test case.

• Prevented the program test suite from running an unnecessary variant to save execution time.

• macOS: Ignored differences from GUI framework error traces in headless runs in output comparisons.

• Reflected test for Nuitka, where it compiles itself and compares its operation has been restored to functional state.

• Used the new method to clear internal caches if available for reference counts.

• Disabled running nested loops test with Python 2.6.

• Containers: Detected Python 2 defaulting containers in Podman tooling.

Cleanups

• UI: Fix, there was a double space in the Windows Runtime DLLs inclusion message. (Fixed in 4.0.1 already.)

• Onefile: Separated files and defines for extra includes for onefile boot and Python build.

• Scons: Provided nicer errors in case of “unset” variables being used, so we can tell it.

• Refactored the process execution results to correctly utilize our namedtuples variant, that makes it easier to understand what code does with the results.

• Quality: Enabled automatic conversion of em-dashes and en-dashes in code comments to the autoformat tool. AI won’t stop producing them and they can cause SyntaxError for older Python versions, nor is unnecessarily using UTF-8 welcome.

• Ensured that cloned outline nodes are assigned their correct names immediately upon creation, that avoids inconsistencies during their creation.

• Quality: Updated to the latest versions of black and adopted a faster isort execution by caching results.

• Quality: Modified the PyLint wrapper to exit gracefully instead of raising an error when no matching files require checking.

• Quality: Avoided checking YAML package configuration files twice, since autoformat already handles them.

• Quality: Ensured that YAML package configuration checks output the original filename instead of the temporary one when a failure occurs.

• Quality: Prevented pushing of tags from triggering git pre-push quality checks.

• Quality: Silenced the output of optipng and jpegoptim during image optimization auto-formatting.

• Visual Code: Added the generated Python alias path file to the ignore list.

• Quality: Enabled auto-formatting for the Nuitka devcontainer configuration file.

• Watch: Avoided absolute paths in compilation to make reports more comparable across machines.

• Quality: Changed mdformat checks to run only once and silently.

• Scons: Disabled format security errors in debug mode and moved Python-related warning disables into common build setup code.

• Quality: Updated to the latest deepdiff version.

• Scons: Avoided MSVC telemetry since it can produce outputs that break CI.

• Debugging: Enhanced non-deployment handler for importing excluded modules.

• Split import module finding functionality into more pieces for enhanced readability.

• Debugging: Added more assertions for constants loading and checking.

• macOS: Dropped the universal target arch.

• Debugging: Added more traces for deep hash verification.

Summary

This release builds on the scalability improvements established in 4.0, with enhanced Python 3.14 support, expanded package compatibility, and significant optimization work.

The --project option seems usable now.

Python 3.14 support remains experimental, but only barely made the cut, and probably will get there in hotfixes. Some of the corrections came in so late before the release, that it was just not possible to feel good about declaring it fully supported just yet.

May 20, 2026 10:00 PM UTC

Django Weblog

Django 6.1 alpha 1 released

Django 6.1 alpha 1 is now available. It represents the first stage in the 6.1 release cycle and is an opportunity to try out the changes coming in Django 6.1.

Django 6.1 offers a harmonious mélange of new features and usability improvements, which you can read about in the in-development 6.1 release notes.

This alpha milestone marks the feature freeze. The current release schedule calls for a beta release in about a month and a release candidate roughly a month after that. We'll only be able to keep this schedule with early and frequent testing from the community. Updates on the release schedule are available on the Django forum.

As with all alpha and beta packages, this release is not for production use. However, if you'd like to take some of the new features for a spin, or help find and fix bugs (which should be reported to the issue tracker), you can grab a copy of the alpha package from our downloads page or on PyPI.

The PGP key ID used for this release is Jacob Walls: 131403F4D16D8DC7

May 20, 2026 07:40 PM UTC

death and gravity

reader 3.24 released – help, multi-user updates

Hi there!

I'm happy to announce version 3.24 of reader, a Python feed reader library.

What's new? #

Here are the highlights since reader 3.23.

Context-sensitive help #

In lieu of a tutorial mode, the web app now offers guidance to new users, and has a basic context-sensitive help system. Here's some screenshots:

new user / empty state

context-sensitive help

also help

Structured logging #

reader now uses structured logging internally, through structlog.

By default, output goes to stdlib logging, but you can opt into structlog-native logging:

import reader, structlog
reader.enable_structlog()
structlog.configure(...)

This was relatively challenging to do, since as a library, you cannot configure logging, nor change any global state. I hope I can contribute a variant of the solution upstream, but meanwhile here's a recipe you can use in your library (warning: brittle code).

Make update_feeds() parallel again #

It turns out the "extensive rework of the parser internal API" from 3.15 caused update_feeds() to retrieve feeds in the main thread regardless of the worker count.

Protip

If you have a parallel map() that returns @contextmanagers, make sure the work you need to do in parallel doesn't happen in __enter__. 😅

New contributors #

Thank you to the new contributors that submitted pull requests to this release!

Want to contribute? Check out the docs and the roadmap.

Hosted reader status update #

As I said last time, I'm working on a hosted version of reader. Background: Why another feed reader web app?, Why not just self-host it?.

Multi-user feed updates #

One of the bigger changes for hosted reader was handling multi-user feed updates.

For intentional but questionable reasons, users have their own dedicated databases, with the web app routing to the appropriate one based on session information.

However, updating feeds should happen in a single, shared database; this allows:

• retrieving feeds once, not once per user
• per-host rate limiting
• preserving a longer history for public feeds

This is now done, complete with a design document (to be published). As a teaser, here's a neat architecture / data flow diagram:

OK, so what now? #

Since I'm rapidly running out of technical things to do, a launch is imminent.

This is what is finished so far:

• multi-user version of the web app
• authentication via email
• infrastructure deployments using pyinfra
• (new) multi-user feed updates
• (new) tutorial mode – context-sensitive help should do

Remaining work to an MVP:

• public demo
• landing page
• give it a good name
• launch announcement + roadmap

Meanwhile, if this sounds like something you'd like to use, get in touch.

That's it for now. For more details, see the full changelog.

Learned something new today? Share it with others, it really helps! PyCoder's Weekly HN Bluesky linkedin Twitter

What is reader? #

reader takes care of the core functionality required by a feed reader, so you can focus on what makes yours different.

reader allows you to:

• retrieve, store, and manage Atom, RSS, and JSON feeds
• mark articles as read or important
• add arbitrary tags/metadata to feeds and articles
• filter feeds and articles
• full-text search articles
• get statistics on feed and user activity
• import / export feeds as OPML
• write plugins to extend its functionality

...all these with:

• a stable, clearly documented API
• excellent test coverage
• fully typed Python

To find out more, check out the GitHub repo and the docs, or give the tutorial a try.

Why use a feed reader library? #

Have you been unhappy with existing feed readers and wanted to make your own, but:

• never knew where to start?
• it seemed like too much work?
• you don't like writing backend code?

Are you already working with feedparser, but:

• want an easier way to store, filter, sort and search feeds and entries?
• want to get back type-annotated objects instead of dicts?
• want to restrict or deny file-system access?
• want to change the way feeds are retrieved by using Requests?
• want to also support JSON Feed?
• want to support custom information sources?

... while still supporting all the feed types feedparser does?

If you answered yes to any of the above, reader can help.

The reader philosophy #

• reader is a library
• reader is for the long term
• reader is extensible
• reader is stable (within reason)
• reader is simple to use; API matters
• reader features work well together
• reader is tested
• reader is documented
• reader has minimal dependencies

May 20, 2026 04:44 PM UTC

Real Python

How to Use the Claude API in Python

The fastest way to use the Claude API in Python is to install anthropic, set your API key, and call client.messages.create(). You’ll have a working response in under a minute:

Example of Using the Claude API in Python

Claude is Anthropic’s large language model, accessible via a clean REST API with an official Python SDK. Unlike heavier AI frameworks that require you to wire up multiple components before you see any output, the anthropic package gets you to a working response in a handful of lines.

In the following steps, you’ll install the anthropic SDK, call Claude from Python, shape Claude’s behavior with a system prompt, and then return structured JSON output using a schema or Pydantic.

Note: Claude’s responses are non-deterministic, so the same prompt produces different output each time, which is expected for a large language model. Also, API calls cost money based on the number of tokens processed. Keep an eye on your usage in the Claude Console as you follow along.

Each step builds on the last, and the final script is short enough to read in one sitting but complete enough to extend into a real application of your own.

Get Your Code: Click here to download the free sample code that shows you how to use the Claude API in Python.

Take the Quiz: Test your knowledge with our interactive “How to Use the Claude API in Python” quiz. You’ll receive a score upon completion to help you track your learning progress:

---

Interactive Quiz

How to Use the Claude API in Python

Test your understanding of using the Claude API in Python. Send prompts, set system instructions, and return structured JSON with a schema.

Prerequisites

Before diving in, make sure you have the following in place:

• Python knowledge: You should be comfortable with Python basics, like defining functions, running scripts from the terminal, and working with virtual environments. If virtual environments are new to you, Python Virtual Environments: A Primer has you covered before you continue.

• Python 3.9 or higher: The anthropic SDK requires Python 3.9 as a minimum. If you’re not sure which version you have, run python --version in your terminal. If you need to install or upgrade, follow the steps in the guide on installing Python.

• An Anthropic account: You’ll need an Anthropic account to generate an API key in the Claude Console. Step 1 will show you how to find and secure your key once you’re in.

Don’t worry if you’ve never worked with an API before. This tutorial will walk you through authentication and help you make your first request from scratch.

Step 1: Set Up the Claude API in Python

Before you can call Claude from Python, you need an API key and the anthropic package installed. By the end of this step, you’ll have both, and Claude will be responding to your first prompt.

Get Your API Key and Install anthropic

Log in to the Claude Console or create a new account. If you’re starting fresh, you can begin using the API after adding $5 of credits.

Then navigate to the API Keys section. Click Create Key, give it a descriptive name like real-python-tutorial, and copy it immediately. You won’t see it again after you close the dialog.

Note: Never paste your API key directly into your code. Instead, store it as an environment variable. The anthropic SDK automatically reads it from ANTHROPIC_API_KEY at runtime, so you never need to reference it explicitly in your scripts.

Storing your key as an environment variable means it never touches your source code or version control history. The exact command depends on your operating system:

• Windows
• Linux + macOS

Language: PowerShell Script

PS> $env:ANTHROPIC_API_KEY="your-api-key-here"

Language: Shell

$ export ANTHROPIC_API_KEY="your-api-key-here"

With your API key stored safely, you’re ready to install the SDK. Create a fresh virtual environment and activate it before installing anything. This isolation prevents the anthropic package from conflicting with your system-level tools.

• Windows
• Linux + macOS

Language: PowerShell Script

PS> python -m venv venv
PS> venv\Scripts\activate
(venv) PS> python -m pip install anthropic

Language: Shell

$ python -m venv venv/
$ source venv/bin/activate
(venv) $ python -m pip install anthropic

Send Your First Prompt

Read the full article at https://realpython.com/claude-api-python/ »

[ Improve Your Python With 🐍 Python Tricks 💌 – Get a short & sweet Python Trick delivered to your inbox every couple of days. >> Click here to learn more and see examples ]

May 20, 2026 02:00 PM UTC

Quiz: How to Use the Claude API in Python

In this quiz, you’ll test your knowledge of How to Use the Claude API in Python.

By working through this quiz, you’ll revisit how to install the anthropic SDK, send prompts to Claude with client.messages.create(), shape responses with a system parameter, and return structured JSON output using a schema or Pydantic.

[ Improve Your Python With 🐍 Python Tricks 💌 – Get a short & sweet Python Trick delivered to your inbox every couple of days. >> Click here to learn more and see examples ]

May 20, 2026 12:00 PM UTC

Python GUIs

Adding QComboBox to a QTableView and getting/setting values after creation — Use QItemDelegate to embed combo boxes in your table views, with per-row data and value tracking

I'm using a QTableView to display data, and would like to limit the choices in some of the fields using a drop-down. I can use QComboBox to provide a list of choices in a normal UI, but how can I do that in a table view?

When you're working with QTableView in PyQt6, you'll sometimes want cells that offer a dropdown selection instead of plain text. A QComboBox is the natural fit here — but embedding one inside a table view takes a bit of wiring up.

In this tutorial, we'll walk through how to use a QItemDelegate to place a QComboBox into specific cells of a QTableView. We'll also cover how to populate each combo box with different items per row, and how to retrieve the selected value so you can use it elsewhere in your application.

How delegates work in Qt's Model/View framework

Qt's Model/View architecture separates your data (the model) from how it's displayed (the view). Between these two sits the delegate, which controls how individual cells are rendered and edited. When you want a cell to use a widget like a combo box instead of a plain text editor, you create a custom delegate.

The delegate has a few methods you'll override:

• createEditor() — creates the widget (in our case, a QComboBox) when the user starts editing a cell.
• setEditorData() — populates the editor widget with the current data from the model.
• setModelData() — writes the user's selection back into the model.
• updateEditorGeometry() — makes sure the widget is sized and positioned correctly inside the cell.

Let's build this up step by step.

Setting up the model and view

First, let's create a simple application with a QTableView and a QStandardItemModel. Each row will represent a software package, and one of the columns will hold a list of available versions. We'll store those version lists directly in the model data, so each row can have its own set of options.

import sys
from PyQt6.QtWidgets import (
    QApplication, QMainWindow, QTableView, QComboBox, QItemDelegate,
)
from PyQt6.QtGui import QStandardItemModel, QStandardItem
from PyQt6.QtCore import Qt, QItemDataRole


class MainWindow(QMainWindow):
    def __init__(self):
        super().__init__()
        self.setWindowTitle("QComboBox in QTableView")

        self.table = QTableView()
        self.setCentralWidget(self.table)

        # Create a model with 3 rows and 2 columns.
        self.model = QStandardItemModel(3, 2)
        self.model.setHorizontalHeaderLabels(["Package", "Version"])

        # Each row has a package name and a list of available versions.
        packages = [
            ("Widget Library", ["1.0", "1.1", "2.0", "2.1"]),
            ("Data Toolkit", ["0.9", "1.0"]),
            ("Render Engine", ["3.0", "3.1", "3.2", "4.0"]),
        ]

        for row, (name, versions) in enumerate(packages):
            # Column 0: package name (plain text).
            self.model.setItem(row, 0, QStandardItem(name))

            # Column 1: store the version list in the item's data.
            # We use Qt.ItemDataRole.UserRole to keep the full list alongside the display text.
            item = QStandardItem(versions[-1])  # Display the latest version by default.
            item.setData(versions, Qt.ItemDataRole.UserRole)
            self.model.setItem(row, 1, item)

        self.table.setModel(self.model)

        # Apply our custom delegate to column 1.
        delegate = ComboDelegate(self.table)
        self.table.setItemDelegateForColumn(1, delegate)

        self.resize(400, 200)

Notice how we store the list of versions using Qt.ItemDataRole.UserRole. This is a custom data role — it lets us attach extra information to a model item without interfering with the text that's displayed (which uses Qt.ItemDataRole.DisplayRole). Each row gets its own version list, so when the combo box opens, it will show only the versions relevant to that row.

Creating the combo box delegate

Now let's write the ComboDelegate class. This is where the combo box gets created and connected to the model.

class ComboDelegate(QItemDelegate):
    """
    A delegate that places a QComboBox in cells of the assigned column.
    """

    def createEditor(self, parent, option, index):
        # Create the combo box and populate it with the version list for this row.
        combo = QComboBox(parent)
        versions = index.data(Qt.ItemDataRole.UserRole)
        if versions:
            combo.addItems(versions)
        return combo

    def setEditorData(self, editor, index):
        # Set the combo box to show the currently selected value.
        current_text = index.data(Qt.ItemDataRole.DisplayRole)
        idx = editor.findText(current_text)
        if idx >= 0:
            editor.setCurrentIndex(idx)

    def setModelData(self, editor, model, index):
        # Write the selected value back into the model.
        model.setData(index, editor.currentText(), Qt.ItemDataRole.DisplayRole)

    def updateEditorGeometry(self, editor, option, index):
        editor.setGeometry(option.rect)

Let's walk through each method:

createEditor() is called when the user double-clicks (or otherwise activates) a cell in column 1. We create a fresh QComboBox, pull the version list from Qt.ItemDataRole.UserRole for that specific row, and add those items to the combo box. Because each row stores its own list, different rows will show different options.

setEditorData() makes sure the combo box starts with the right item selected. We read the current display text from the model and find the matching entry in the combo box.

setModelData() fires when the user finishes editing (for example, by clicking away from the cell). It takes whatever the user selected in the combo box and writes it back into the model's DisplayRole.

updateEditorGeometry() simply ensures the combo box fills the cell neatly.

Running the application

Add the standard entry point at the bottom of your script:

app = QApplication(sys.argv)
window = MainWindow()
window.show()
sys.exit(app.exec())

Run the script and double-click any cell in the "Version" column. You'll see a combo box appear with the version options for that specific row. Select a value, click away, and the cell updates.

Getting the selected value

After the user makes a selection, the value is stored in the model. You can read it at any time:

# Read the selected version for row 0.
selected = self.model.item(0, 1).text()
print(f"Row 0 selected version: {selected}")

If you want to react immediately when a selection changes, you can connect to the model's dataChanged signal. If you're new to how signals work in Qt, see our guide on signals, slots and events:

self.model.dataChanged.connect(self.on_data_changed)

def on_data_changed(self, top_left, bottom_right, roles):
    if top_left.column() == 1:
        row = top_left.row()
        value = top_left.data(Qt.ItemDataRole.DisplayRole)
        print(f"Row {row} version changed to: {value}")

This approach keeps things nicely separate — you're working through the model rather than trying to hold references to individual combo box widgets. The combo boxes are created and destroyed as the user interacts with cells.

Setting a value programmatically

To change a cell's value from code, update the model directly:

# Set row 2's version to "3.1".
self.model.item(2, 1).setText("3.1")

The next time the user opens the combo box on that row, the delegate's setEditorData() will position the combo box on "3.1".

You can also update the list of available versions for a row:

# Add a new version to row 1's options.
item = self.model.item(1, 1)
versions = item.data(Qt.ItemDataRole.UserRole)
versions.append("1.1")
item.setData(versions, Qt.ItemDataRole.UserRole)

Why each row gets its own combo box items

A common stumbling block is ending up with the same items in every combo box across the column. This happens when you store the item list on the delegate itself (as a single shared list) rather than on the model. Since the delegate is shared across all rows, any list stored on it will be the same everywhere.

The solution, as we've done here, is to store per-row data in the model using Qt.ItemDataRole.UserRole. Each call to createEditor() reads from the specific index it's given, so each row naturally gets its own set of options. This is a pattern you'll use often when different rows need different editor configurations.

Complete code

Here's the full working example in one block:

import sys
from PyQt6.QtWidgets import (
    QApplication, QMainWindow, QTableView, QComboBox, QItemDelegate,
)
from PyQt6.QtGui import QStandardItemModel, QStandardItem
from PyQt6.QtCore import Qt


class ComboDelegate(QItemDelegate):
    """
    A delegate that places a QComboBox in cells of the assigned column.
    """

    def createEditor(self, parent, option, index):
        combo = QComboBox(parent)
        versions = index.data(Qt.ItemDataRole.UserRole)
        if versions:
            combo.addItems(versions)
        return combo

    def setEditorData(self, editor, index):
        current_text = index.data(Qt.ItemDataRole.DisplayRole)
        idx = editor.findText(current_text)
        if idx >= 0:
            editor.setCurrentIndex(idx)

    def setModelData(self, editor, model, index):
        model.setData(index, editor.currentText(), Qt.ItemDataRole.DisplayRole)

    def updateEditorGeometry(self, editor, option, index):
        editor.setGeometry(option.rect)


class MainWindow(QMainWindow):
    def __init__(self):
        super().__init__()
        self.setWindowTitle("QComboBox in QTableView")

        self.table = QTableView()
        self.setCentralWidget(self.table)

        self.model = QStandardItemModel(3, 2)
        self.model.setHorizontalHeaderLabels(["Package", "Version"])

        packages = [
            ("Widget Library", ["1.0", "1.1", "2.0", "2.1"]),
            ("Data Toolkit", ["0.9", "1.0"]),
            ("Render Engine", ["3.0", "3.1", "3.2", "4.0"]),
        ]

        for row, (name, versions) in enumerate(packages):
            self.model.setItem(row, 0, QStandardItem(name))
            item = QStandardItem(versions[-1])
            item.setData(versions, Qt.ItemDataRole.UserRole)
            self.model.setItem(row, 1, item)

        self.table.setModel(self.model)

        delegate = ComboDelegate(self.table)
        self.table.setItemDelegateForColumn(1, delegate)

        # React to changes.
        self.model.dataChanged.connect(self.on_data_changed)

        self.resize(400, 200)

    def on_data_changed(self, top_left, bottom_right, roles):
        if top_left.column() == 1:
            row = top_left.row()
            value = top_left.data(Qt.ItemDataRole.DisplayRole)
            print(f"Row {row} version changed to: {value}")


app = QApplication(sys.argv)
window = MainWindow()
window.show()
sys.exit(app.exec())

Wrapping up

Using a custom QItemDelegate gives you full control over how cells in a QTableView are edited. By storing per-row data in the model with Qt.ItemDataRole.UserRole, you can give each combo box its own set of items — solving the common problem of all combo boxes showing the same options.

The pattern here — store data in the model, read it in the delegate, write changes back to the model — works well beyond combo boxes. You can use the same approach to embed spin boxes, date pickers, or any other widget into your table cells. Once you're comfortable with this flow, you'll find Qt's Model/View framework surprisingly flexible. For a deeper dive into using QTableView with real-world data sources like NumPy and Pandas, see our QTableView with numpy and pandas tutorial. You can also explore how to make table cells editable for other common editing patterns.

For an in-depth guide to building Python GUIs with PyQt6 see my book, Create GUI Applications with Python & Qt6.

May 20, 2026 06:00 AM UTC

May 19, 2026

PyCoder’s Weekly

Issue #735: Agentic Architecture, Python is Weird, 3.15, and More (2026-05-19)

#735 – MAY 19, 2026
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Harness Orchestration: The Next Primitive for AI Agents

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May 19, 2026 07:30 PM UTC

Real Python

Tapping Into the Zen of Python

The Zen of Python is a collection of 19 aphorisms that capture the guiding principles behind Python’s design. You can display them anytime by running import this in a Python REPL. Tim Peters wrote them in 1999 as a joke, but they became an iconic part of Python culture that was even formalized as PEP 20.

By the end of this video course, you’ll understand:

• The Zen of Python is a humorous poem of 19 aphorisms describing Python’s design philosophy
• Running import this in a Python interpreter displays the complete text of the Zen of Python
• Tim Peters wrote the Zen of Python in 1999 as a tongue-in-cheek comment on a mailing list
• The aphorisms are guidelines, not strict rules, and some intentionally contradict each other
• The principles promote readability, simplicity, and explicitness while acknowledging that practicality matters

Experienced Pythonistas often refer to the Zen of Python as a source of wisdom and guidance, especially when they want to settle an argument about certain design decisions in a piece of code. In this video course, you’ll explore the origins of the Zen of Python, learn how to interpret its mysterious aphorisms, and discover the Easter eggs hidden within it.

You don’t need to be a Python master to understand the Zen of Python! But you do need to answer an important question: What exactly is the Zen of Python?

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May 19, 2026 02:00 PM UTC

Quiz: Absolute vs Relative Imports in Python

In this quiz, you’ll test your understanding of Absolute vs Relative Imports in Python.

By working through this quiz, you’ll revisit how Python’s import system resolves modules, the differences between absolute and relative imports, and the PEP 8 conventions for styling import statements.

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May 19, 2026 12:00 PM UTC

Quiz: Tapping Into the Zen of Python

In this quiz, you’ll test your understanding of Tapping Into the Zen of Python.

By working through this quiz, you’ll revisit the origins of the poem, the meaning of several aphorisms, and the inside jokes hidden throughout.

The questions explore how the principles apply in practice and when it’s okay to bend the rules in the name of practicality.

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May 19, 2026 12:00 PM UTC

PyCharm

LLM Evaluation and AI Observability for Agent Monitoring

This is a guest post from Naa Ashiorkor, a data scientist and tech community builder.

Artificial intelligence keeps evolving at a rapid pace. The latest major application of AI, specifically of LLMs, is AI agents. These are systems that use their perception of their environment, processes, and input to take action to achieve specific goals, and they are built on LLMs. 

Increasingly, complex AI agents are being used in real-world applications. While simpler agentic applications that use only one agent to achieve a goal still exist, organizations are now shifting towards multi-agent systems that use multiple subagents coordinated by a main agent. These are more adaptable and can mimic human teams when it comes to performing specialized tasks such as data analysis, compliance, customer support, and more. The reasoning and autonomy of AI agents have improved; consequently, they can gather data, conduct cross-references, and generate analysis.

As we move towards these complex, real-world applications of agents, an ever-stronger spotlight is being shone both on how we observe AI agents and how we evaluate the LLMs they’re built upon. The complexity, interactions, and autonomous processes under the surface of AI agents make rigorous monitoring and assessment an essential part of building and maintaining these applications. LLM evaluation determines if the AI agent can work, while AI agent observability determines if it is working. LLM evaluation tests an agent’s basic capabilities before and during deployment, while agent observability provides deep, real-time visibility into an agent’s internal reasoning and operational health once it is live. It is pretty obvious that having just one of these is a loss and a formula for failure. 

In this blog post, we’ll explore how to evaluate agents using advanced metrics and observability tools. It’s designed as a practical, end-to-end reference for teams that want to move beyond demos and actually run AI agents in live, real-world environments, avoiding the common pitfalls that cause failure in production.

Core LLM evaluation metrics for modern AI systems

As LLMs are now applied to a wide range of use cases, it is important that their evaluation covers both the tasks they may perform and their potential risks. Evaluation metrics give a better understanding of the strengths and weaknesses of LLMs, influence the guidance of human-LLM interactions, and highlight the importance of ensuring LLM safety and reliability. Hence, LLM evaluation metrics for assessing the performance of an LLM are indispensable in modern AI systems. Without well-defined evaluation metrics, assessing model quality becomes subjective. 

There are several key evaluation metrics, each with a different purpose, and the table below provides a summary of some of them.

Hallucination rate

Hallucinations in LLMs produce outputs that seem convincing yet are factually unsupported and can be categorized as either intrinsic, where the output contradicts the source content, or extrinsic, where it simply cannot be verified. They can stem from a range of factors across data, training, and inference, from quality issues in the large datasets used for initial training and the data used to fine-tune model behavior to post-training techniques that make models overly eager to provide responses to imperfect decoding strategies at inference. Because hallucination is an unsolved challenge cutting across every stage of model development, measuring and assessing it remains a vital part of LLM evaluation.

There is a wide variety of techniques for detecting hallucinations. These include: 

• Fact-checking: Extracting independent factual statements from the model’s outputs (fact extraction) and then verifying these against trusted knowledge sources (fact verification).
• Uncertainty estimation: Using the certainty provided in the model’s internal state to estimate how likely a piece of factual content is to be a hallucination.
• Faithfulness hallucination detection: Ensures the faithfulness of LLMs to provide context or user instructions. 

There are several metrics for hallucination detection. Some of the most commonly used metrics include:

• Fact-based metrics: Assessing faithfulness by measuring the overlap of facts between the generated content and the source content. 
• Classifier-based metrics: Utilizing trained classifiers to distinguish between the level of entailment between the generated content and the source content. 
• QA-based metrics: Using question-answering systems to validate the consistency of information between the source content and the generated content. 
• Uncertainty-based metrics: Assessing faithfulness by measuring the model’s confidence in its generated outputs. 
• LLM-based metrics: Using LLMs as evaluators to assess the faithfulness of generated content through specific prompting strategies. 

PyCharm’s Hugging Face integration lets you discover evaluation models and datasets without leaving the IDE. Use the Insert HF Model feature to search for hallucination or toxicity classifiers, and hover over any model or dataset name in your code to instantly preview its model card, including training data, intended use, and limitations. This means you can import a dataset, evaluate your LLM, and verify the tools you’re using, all from one place.

Trust is imperative in the acceptance and adoption of technology. Trust in AI is especially important in areas such as healthcare, finance, personal assistance, autonomous vehicles, and others. Hallucinations have a huge impact on users’ trust in LLMs.

In 2023, a story went viral about a Manhattan lawyer who submitted a legal brief largely generated by ChatGPT. The judge quickly noticed how different it was from a human-written submission, revealing clear signs of hallucination. Incidents like this highlight the real-world risks of LLM errors and their impact on user trust. As people encounter more examples of hallucination, skepticism around LLM reliability continues to grow.

Toxicity scores

LLMs that have been pretrained on large datasets from the web have the tendency to generate harmful, offensive, and disrespectful content as well as toxic language, such as hate speech, harassment, threats, and biased language, which have a negative impact on their safe deployment. Toxicity detection is the process of identifying and flagging toxic content by integrating open-source tools or APIs into the LLM workflow to analyze both the user input and the LLM output. Some of the available toxicity tools include the OpenAI Moderation API, which is free, works with any text, and has a quick implementation. Perspective API by Google is also widely used with a transparent methodology, but will no longer be in service after 2026. Detoxify, which is open source, has no API costs, and is Python-friendly, and Azure AI Content Safety by Microsoft, which is customizable and best for enterprise deployments and existing Azure users. Hugging Face Toxicity Models have many model options and easy integration with Transformers.

Toxicity detection has become a guardrail; hence, it is important in public-facing applications. They prevent toxic content from reaching users, which protects both individuals and organizations. In public-facing applications, toxicity detection operates by input filtering, output monitoring, and real-time scoring. This prevents attacks where users intentionally train AI to produce toxic content through coordinated toxic inputs; toxic content will never reach the user, even if produced by the underlying AI, so systems can adjust their behavior dynamically based on conversation content and escalating risks. Unguarded AI can be exploited, which leads to reputational damage. 

For toxicity evaluation, PyCharm’s Hugging Face Insert HF Model feature helps you discover classifiers like s-nlp/roberta_toxicity_classifier directly in the IDE. Hovering over the model name reveals its model card, where you can see it was trained on the Jigsaw toxic comment datasets, helping you understand what the model can and can’t detect before you write a single line of evaluation code. 

Frameworks for LLM evaluation

Frameworks for LLM evaluation have changed the game; teams don’t have to rely on manual reviews, gut instinct, and subjective judgment to assess model quality. These frameworks automate the measurement of model quality using standardized, quantifiable metrics. They assign numerical scores to outputs that measure faithfulness, relevancy, toxicity, and other important dimensions. This automation results in reproducibility, speed, and objectivity. 

Consequently, the same input always produces the same score; evaluation runs 10–100 times faster, so in minutes instead of days; and there are no more debates on the quality of the output. Some of these frameworks include DeepEval and Retrieval Augmented Generation Assessment (Ragas). DeepEval is an open-source evaluation framework built with seven principles in mind, such as the ability to easily “unit test” LLM outputs in a similar way to Pytest and plug in and use over 50 LLM-evaluated metrics, most of which are backed by research and all of which are multimodal. 

It is extremely easy to build and iterate on LLM applications with two modes of evaluation, namely, end-to-end LLM evals and component-level LLM evals. It is used for comprehensive testing across RAG, agents, and chatbots. Ragas is a framework for reference-free evaluation of RAG pipelines. There are several dimensions to consider, such as the ability of the retrieval system to identify relevant and focused context passages, as well as the capability of the LLM to exploit such passages in a faithful way; hence, it is challenging to evaluate RAG systems. Ragas provides a suite of metrics for evaluating these dimensions without relying on ground-truth human annotations. 

The limits of static prompt evaluation

Traditional LLM evaluation methods are useful for single prompt-response pairs, measuring output quality, RAG systems with straightforward retrieval, and static evaluation with fixed inputs. But they are limited for multi-step agents because LLM evaluation focuses on the final output quality, not the decision-making process that produced it. Multi-step agents exhibit a different kind of complexity, as they chain multiple decisions.

Why traditional LLM evaluation isn’t enough for agents 

Agents operate independently within complex workflows, and this independence can introduce challenges such as deviation from expected behavior, errors in production, and more failure points than in traditional software applications. Hence, an agent can perform well in testing but fail in production. Traditional LLM evaluations don’t have the capacity to test such use cases. Testing is usually done in a controlled environment with limited scenarios, but production involves real users, edge cases, unpredictable inputs, and scale. This means that agents can make decisions that are not seen in testing, and in production, tasks could be completed, though incorrectly, without generating an error signal. This is where advanced evaluation and monitoring practices come to the rescue! They provide the visibility and systematic measurement needed to deploy agents confidently, rather than relying on trial and error.

The complexity of agent behavior

Traditional LLM evaluation measures single prompt-response pairs: provide an input prompt, receive an output response, and measure quality through metrics such as accuracy, relevance, and faithfulness. Due to the complexity and non-deterministic, multi-step reasoning of AI agents, they cannot be reliably evaluated using traditional evaluation metrics.

Agent behavior is complex, and this complexity introduces challenges. Agents operate in dynamic environments where APIs might be down, databases change between queries, and the “right” answer depends on current conditions. They can use external tools and APIs to complete tasks, and may either use the wrong tool or use the right tool with the wrong parameters or input type. Their internal reasoning traces remain hidden unless they are logged explicitly, so it might be challenging to determine whether an agent was successful through logic or chance. An agent’s output could be perfectly correct despite poor internal decisions, or the entire task could fail despite correct step execution.

This is where observability tooling becomes essential. PyCharm’s AI Agents Debugger breaks open the black box of agentic systems, letting you trace LangGraph workflows and inspect each agent node’s inputs, outputs, and reasoning directly in the IDE, with zero extra code. Just install the plugin, run your agent, and the debugger automatically captures execution traces. Click the Graph button to visualize the full workflow, making it easy to spot where an agent chose the wrong tool, passed bad parameters, or succeeded by luck rather than logic.

To see this in action, I built a simple travel-planning agent using LangGraph in two steps: a research node that suggests summer destinations based on my preferences, and a plan node that picks the best option and builds a three-day itinerary. With the AI Agents Debugger, you can trace exactly what information flowed between these two steps – what the research node suggested and how the planner used those suggestions to build the final itinerary.

Advanced agent evaluation metrics

The complexity of AI agents demands evaluation that goes beyond considering the final output quality, that is, measuring whether it is accurate, relevant, and grounded. Specialized agent evaluation assesses the complete decision-making process, including the planning logic, tool selection, parameter construction, reasoning coherence, and resource efficiency that led to the final output. Hence, the advanced agent evaluation metrics are designed to make such a process visible and measurable. Some of them are task completion rate, tool usage, reasoning quality, efficiency, and error handling.

Task completion rate

Task completion rate measures the percentage of tasks where an agent successfully achieves the end goal. This is calculated as the number of completed tasks divided by the total number of tasks attempted. The context of “completed” differs by use case. There are real-world use cases for task completion rate. Let’s start with a basic use case. Consider a customer service agent handling a specific food delivery order: “Where is my order #0001? It has not been delivered to me.” Completion rate means successfully looking up the order ID, retrieving the tracking information, and providing an accurate delivery estimate, so all three steps must succeed. If the agent retrieves the wrong order or fails to assess the tracking system, that is a failed task, even if it produces the same output. 

Next, let us look at a medium-complexity use case, sequential API calls. Consider an agent tasked with creating a Jira support ticket and notifying the relevant team in Slack. The agent calls the Jira API to create a ticket, parses the response to get the ticket ID, calls the Slack API with the ticket link, and finally verifies the success of both. If the agent successfully creates the Jira ticket, but the Slack notification fails, that is considered a failed task even if the ticket exists in Jira, since the team wasn’t notified. 

Finally, let’s examine a high-complexity use case: An agent is given the task of completing an online purchase, which means it must handle everything from checkout to order confirmation. Six steps are involved: Verify the item is still in stock, process the payment with a credit or debit card, reserve or decrement inventory, create an order record, generate an order confirmation number, and send a confirmation email to the customer. If the agent successfully charges the customer’s card but the confirmation email fails to send, that’s a failed task, even if the payment was processed and the order was created. In such a situation, the customer has no proof of purchase, so they will likely contact support or attempt to purchase again.

Tool usage correctness

Tool usage correctness assesses whether an agent correctly identifies and invokes the relevant tools and APIs. It is a deterministic measure that is assessed using techniques such as LLM as a judge, like most LLM evaluation metrics. It has three dimensions: 

• Did the agent choose the right tool for the task (tool selection)? 
• Were the parameters constructed correctly (input parameters)? 
• Did the agent properly use the tool results (output handling)? 

Hence, it is important for reliability and functional correctness. 

Step-by-step reasoning accuracy

In real-world use cases, an LLM agent’s reasoning is shaped by much more than just the model itself. Modern frameworks such as LangChain expose the agent’s internal “thoughts” through structured logging of intermediate reasoning steps. This is done using the ReAct (Reasoning and Acting) pattern, which involves the agent thinking about what to do, using a tool, observing the tool result, and then repeating until the task is complete. Each “thought” is logged as text, which creates a complete trace of the reasoning process from initial query to final answer. These traces can be extracted programmatically and evaluated to assess whether the agent’s logic is sound even when the final output appears correct. Evaluating planning steps involves assessing aspects such as the overall approach’s logic, the ordering of steps, and whether any steps are unnecessary or redundant. Evaluating execution assesses whether the implementation worked, such as whether tools were called with correct parameters, whether each step was completed successfully, whether errors were handled appropriately, and whether the output was interpreted correctly. This can be done seamlessly in PyCharm using the AI Agents Debugger.

Groundedness (faithfulness)

Groundedness, also known as faithfulness, is the most critical metric for retrieval-augmented generation (RAG), which is a common component of agentic applications. It assesses whether the agent’s response is actually supported by the retrieved source documents or whether, instead, the model hallucinated information. Different evaluation techniques include:

• Atomic claim verification: Breaks up the response into atomic claims and checks each claim against the retrieved context. It is slow but best for production RAG and thorough evaluation. 
• Semantic similarity: Compares the embeddings of the response and source documents. It is fast, so it is best for quick checks and first-pass filtering. 
• LLM-as-Judge: works by prompting the LLM to score groundedness by extracting factual statements from the response and then checking each statement against the retrieved context. It offers medium speed and is best for flexible, custom criteria. 

AI observability and why it matters

AI observability is about visibility into what the agent is doing. This covers recording everything that happens when a task is executed, including the agent’s reasoning at each step, which tools were called with what parameters, what data was retrieved, and how decisions were made from start to finish. With such a transparent system where every decision can be logged and traced, teams are able to understand why an agent fails, behaves unexpectedly, or becomes expensive to run because issues can be debugged and behavior can be audited. Consequently, system design improves, and guesswork is eliminated.

Definition of AI observability

AI observability is the real-time monitoring of agent actions, thoughts, and environmental interactions: what went in, what came out, how the agent thought through the problem, and which tools, APIs, and data were used. AI observability builds on the three pillars of DevOps observability – that is, metrics, logs, and traces – but extends each one for AI’s unique needs. DevOps metrics track CPU and latency, while AI metrics track token usage and cost per interaction. DevOps logs capture system errors, while AI logs capture reasoning traces and decision points. DevOps traces follow requests through services, while AI traces follow reasoning through agent steps, tool calls, and observations.

Benefits for agent monitoring

Agent monitoring has immense benefits – here are some of the most important:

• It debugs reasoning errors: When an agent fails or gives an unexpected output, monitoring provides a complete trace of its decision-making process, which shows exactly where the logic broke down. Hence, there is no need to spend hours guessing the causes.
• It measures performance and latency over time: Since metrics such as average latency, token usage, cost per interaction, and completion rates across all queries are tracked, degradation patterns can be identified before they affect users. As a result, performance issues can be identified and resolved before users file any complaints. 
• It identifies regressions after model or prompt updates: Baseline metrics such as completion rate, faithfulness scores, latency, and cost are established and then monitored for deviations after deployments. If a new prompt drops the compilation rate or a model update increases the hallucination rate, automated alerts catch it immediately. Hence, issues are caught before users are affected.

Popular tools for agent monitoring

Several frameworks and platforms have emerged to provide built-in observability for AI agents, with each having different strengths and integration approaches and matching different features and requirements. The choice of the right tool depends on the framework, deployment preferences, and primary needs. The table below shows some popular tools and whether they match different features and requirements.

Best practices for evaluating agents in production

Evaluation does not end after deployment; rather, it is intensified. This continuous evaluation tracks how much the system costs to run, how quickly it responds under various loads, and how it handles errors or unusual inputs. Without such evaluation, problems can only be identified after the users are affected. An agent can pass all the quality checks with excellent faithfulness scores, high completion rates, and strong reasoning but fail in production if costs spiral, latency increases, or edge cases cause instability. Hence, there is a critical need for ongoing evaluation and monitoring, which will lead to systems that are reliable, scalable, and financially sustainable.

Monitor cost and latency

Monitoring cost and latency is critical for production sustainability. Token usage and response time must be tracked continuously because small inefficiencies compound dramatically over time, and the cost per token of the powerful reasoning models used for agents can be high. Production workloads require cost and latency monitoring to identify problems before user experience and budget are impacted. Cost monitoring tracks token usage at different levels, such as per request, per query type, and over time. Without visibility into patterns generated by these, teams end up discovering cost problems through surprise bills. With monitoring, they can proactively cache common queries and optimize prompts to reduce token use. Latency monitoring reveals track response time and component breakdowns to identify bottlenecks.

Cost control in production workloads is important because production costs can spiral quickly, unmonitored systems can exceed budgets, and latency impacts user experience and retention.

Combine offline and online evaluation

Effective agent evaluation requires combining offline and online evaluation, where each addresses gaps the other leaves. Offline evaluation uses fixed test databases for reproducible benchmarking, which enables fast iteration on prompts and models in controlled environments without production risk. Online evaluation monitors real user interactions in production, which reveals edge cases in testing that were never expected, so it is useful for real-time feedback, user data, and observability tools. A combination of both results in an optimal strategy where offline evaluation validates changes before deployment, then online evaluation monitors production reality. 

Use human-in-the-loop when necessary

LLM agents are appreciated for how they have played a positive role in the different ecosystems, but not every agent should run autonomously since they can misinterpret prompts, cross boundaries, or make dreadful errors that can’t be caught by automation alone. Hence, the need for human-in-the-loop failsafes. Human-in-the-loop is also essential during initial setup: Unless teams already have domain-specific evaluation datasets for monitoring the agent, these will need to be created manually by assessing the agent’s performance. A hybrid approach is required when critical decisions require human validation, such as approving transactions, modifying sensitive data, or triggering irreversible workflows. In this approach, it is important that decisions are routed through a human checkpoint before proceeding. The intention is not to slow automation but rather to ensure that the right decisions involve the right oversight. A well-designed human-in-the-loop system delivers compound returns over time. Every human correction becomes feedback, which improves the agent’s accuracy and gradually reduces the need for manual review. Human oversight isn’t treated as a failure but rather as a safety net that makes the system better with use.

Final thoughts

Fundamentally, AI agents are different from single-prompt LLMs. They navigate multi-step workflows, make autonomous decisions, and use external tools, which introduces complexities that demand continuous evaluation, not just static testing. Evaluation must evolve from pre-deployment checkpoints to ongoing monitoring. Production-ready agents aren’t just well-tested; they’re continuously observed and improved based on real behavior. LLM evaluation and AI observability enable faster, safer iteration by catching issues early and feeding production insights back into development.

PyCharm streamlines agent development with integrated debugging, profiling, and testing. Step through reasoning with breakpoints, find cost bottlenecks, and iterate on evaluation tests rapidly. These workflows transform hours of debugging into minutes of systematic investigation. Explore PyCharm for AI development to see how integrated tools can help you build, evaluate, and deploy reliable AI agents.

About the author

Naa Ashiorkor

Naa Ashiorkor is a data scientist and tech community builder. She is deeply involved in the Python community and serves as an organizer for various conferences, including EuroPython. She is currently building PyLadies Tampere.

May 19, 2026 09:46 AM UTC

May 18, 2026

Ari Lamstein

How Remote Work Has Grown — and Shrunk — Since Covid

Remote work surged during Covid — and while it has declined since, it’s still far above pre‑pandemic levels. I just updated my Covid Demographics Explorer with the latest ACS data, and the national trend is striking:

Remote work more than tripled between 2019 and 2021, rising to nearly 28 million people at the height of the pandemic. Since then it has edged down each year, but only modestly. Even today, at about 22 million, it remains roughly 2.5 times the pre‑Covid level.

The app now lets you generate this same graph for every state, as well as for counties and cities with populations of at least 65,000. See how the trend looks where you live.

Exploring Local Trends

I also added a “Compare Years” tab that lets you see which locations saw the biggest change in remote work between any two years. The national trend tells one story, but the local data tells another: the rise and fall of remote work played out very unevenly across the country. Below I run this analysis twice: first for the national increase from 2019-2021, and then for the gradual decline between 2021 and 2024.

The Remote Work Spike: 2019-2021

Between 2019 and 2021, the location that increased the number of remote workers the most was Sunnyvale, California. The number of remote workers there increased almost 11x in two years, from an estimated 3,235 to 38,319. Sunnyvale is in the heart of Silicon Valley, and tech companies were among the fastest to adopt remote work, which helps explain this result:

The scatterplot also shows the broader pattern: most locations cluster between a 150% and 300% increase in remote work during this period. That makes Sunnyvale’s nearly 1,100% jump stand out even more — it’s an order of magnitude beyond the national norm.

Interestingly, only one location in the entire dataset saw a decrease in remote work during this period: Rice County, Minnesota (-7.5%). It’s the lone point below zero on the chart, and I don’t have a clear explanation for it.

The Remote Work Decline: 2021-2024

When we run this same analysis for 2021–2024, we see a very different result: Sunnyvale’s remote workforce shrank by 67.2%, the largest drop in the dataset. This means that Sunnyvale saw both the largest increase between 2019 and 2021 and the largest decrease between 2021 and 2024:

The scatterplot also shows how different the overall pattern is in this period. Instead of large increases, most locations cluster between a 10% and 30% decline in remote work — a sharp contrast with the 2019–2021 graph, where nearly every location saw a substantial increase.

Against this backdrop, Sunnyvale’s 67% drop stands out as an outlier. The likely explanation is the wave of return‑to‑office mandates that swept through the tech industry during this period. The two other largest decreases also happened in Silicon Valley: the city of Fremont (–61%) and Santa Clara County (–56%).

At the other end of the distribution, the few places that saw increases tend to be warm‑weather, high‑amenity destinations: Marion County, Florida (69%), Collier County, Florida (65%), and Maui County, Hawaii (57%) saw the largest gains. These increases may reflect people with remote‑work jobs relocating to places with natural beauty and a high quality of life — a very different dynamic from the employer‑driven declines we see in Silicon Valley.

Conclusion

Three years after the peak, roughly 22 million Americans still work from home — more than double the pre-pandemic baseline. But the story is more complex than a single national number: a dramatic surge, an uneven retreat, and striking differences across the country. How does your corner of the country fit in?

The new version of the Covid Demographics Explorer makes it easy to explore these patterns yourself. In addition to remote‑work trends, you can examine changes in population, median household income, median rent, and public assistance. Analyze your own location.

This app was built in Python with the Streamlit framework. I teach Streamlit for O’Reilly — and if you’d like to learn to build apps like this yourself, I offer a free 7-day email course. Sign up in the form below.

May 18, 2026 08:00 PM UTC

Real Python

Python Built-in Functions: A Complete Guide

Python’s built-in functions are predefined functions you can use anywhere in your code without any imports. They handle common tasks across math, data type creation, iterable processing, and input and output. Knowing which ones to reach for makes your code shorter and more Pythonic.

In this tutorial, you’ll:

• Recognize Python’s built-in functions and the built-in scope they live in
• Use the right built-in for math, data types, iterables, and I/O tasks
• Tell apart true functions and classes that look like functions
• Apply built-ins to solve practical problems without reinventing the wheel

To get the most out of this tutorial, you’ll need to be familiar with Python programming, including topics like working with built-in data types, functions, classes, decorators, scopes, and the import system.

Get Your Code: Click here to download the free sample code that shows you how to use Python’s built-in functions.

Get the PDF Guide: Click here to download a free PDF guide that gives you a complete overview of Python’s built-in functions and how to use them.

Take the Quiz: Test your knowledge with our interactive “Python Built-in Functions: A Complete Guide” quiz. You’ll receive a score upon completion to help you track your learning progress:

---

Interactive Quiz

Python Built-in Functions: A Complete Guide

Test your understanding of Python's built-in functions for math, data types, iterables, and I/O—and when to reach for each one.

Built-in Functions in Python

Python has several functions available for you to use directly from anywhere in your code. These functions are known as built-in functions and they cover many common programming problems, from mathematical computations to Python-specific features.

Note: All these functions live in the builtins module, which Python loads at startup and exposes through the built-in scope, so you can use them anywhere without importing the module. Importing the module explicitly is useful if you know that you’ll shadow a built-in name with one of your own variables or functions. Doing so keeps the original within reach as builtins.name.

Among these built-ins, you’ll also find classes with function-style names like str, tuple, list, and dict, which define built-in data types. These classes are listed in the Python documentation as built-in functions, so they’re covered in this tutorial too.

In this tutorial, you’ll learn the basics of Python’s built-in functions. By the end, you’ll know what their use cases are and how they work. You’ll start with the built-in functions for math computations.

Using Math-Related Built-in Functions

In Python, you’ll find a few built-in functions that take care of common math operations, like computing the absolute value of a number, calculating powers, and more. Here’s a summary of the math-related built-in functions in Python:

Function	Description
abs()	Calculates the absolute value of a number
divmod()	Computes the quotient and remainder of integer division
max()	Finds the largest of the given arguments or items in an iterable
min()	Finds the smallest of the given arguments or items in an iterable
pow()	Raises a number to a power
round()	Rounds a floating-point value
sum()	Sums the values in an iterable

In the following sections, you’ll learn how these functions work and how to use them in your Python code.

Getting the Absolute Value of a Number: abs()

The absolute value or modulus of a real number is its non-negative value. In other words, the absolute value is the number without its sign. For example, the absolute value of -5 is 5, and the absolute value of 5 is also 5.

Note: To learn more about abs(), check out the How to Find an Absolute Value in Python tutorial.

Python’s built-in abs() function allows you to quickly compute the absolute value of a number. Here’s its signature:

Language: Python Syntax

abs(number)

The number argument can be any numeric value, including integers, floating-point numbers, complex numbers, fractions, and decimals. Take a look at a few examples:

Language: Python

>>> from decimal import Decimal
>>> from fractions import Fraction

>>> abs(-42)
42
>>> abs(42)
42

>>> abs(-42.42)
42.42
>>> abs(42.42)
42.42

>>> abs(complex("-2+3j"))
3.605551275463989
>>> abs(complex("2+3j"))
3.605551275463989

>>> abs(Fraction("-1/2"))
Fraction(1, 2)
>>> abs(Fraction("1/2"))
Fraction(1, 2)

>>> abs(Decimal("-0.5"))
Decimal('0.5')
>>> abs(Decimal("0.5"))
Decimal('0.5')

In these examples, you compute the absolute value of different numeric types using the abs() function. First, you use integer numbers, then floating-point and complex numbers, and finally, fractional and decimal numbers. In all cases, when you call the function with a negative value, the final result removes the sign.

For a practical example, say that you need to compute the total profits and losses of your company from a month’s transactions:

Language: Python

>>> transactions = [-200, 300, -100, 500]

>>> incomes = sum(income for income in transactions if income > 0)
>>> expenses = abs(
...     sum(expense for expense in transactions if expense < 0)
... )

>>> print(f"Total incomes: ${incomes}")
Total incomes: $800
>>> print(f"Total expenses: ${expenses}")
Total expenses: $300
>>> print(f"Total profit: ${incomes - expenses}")
Total profit: $500

Read the full article at https://realpython.com/python-built-in-functions/ »

[ Improve Your Python With 🐍 Python Tricks 💌 – Get a short & sweet Python Trick delivered to your inbox every couple of days. >> Click here to learn more and see examples ]

May 18, 2026 02:00 PM UTC

Python Bytes

#480 Proud Parents

<strong>Topics covered in this episode:</strong><br> <ul> <li><strong><a href="https://www.better-simple.com/django/2026/05/06/using-django-tasks-in-production/?featured_on=pythonbytes">Using Django Tasks in production</a></strong></li> <li><strong>Co-authored with Claude?</strong></li> <li><strong><a href="https://rushter.com/blog/pypi-packages/?featured_on=pythonbytes">PyPI packages are increasing rapidly</a></strong></li> <li><strong><a href="https://tildeweb.nl/~michiel/httpx2.html?featured_on=pythonbytes">httpx2</a></strong></li> <li><strong>Extras</strong></li> <li><strong>Joke</strong></li> </ul><a href='https://www.youtube.com/watch?v=-x1R3S72gCU' style='font-weight: bold;'data-umami-event="Livestream-Past" data-umami-event-episode="480">Watch on YouTube</a><br> <p><strong>About the show</strong></p> <p>Sponsored by us! Support our work through:</p> <ul> <li>Our <a href="https://training.talkpython.fm/?featured_on=pythonbytes"><strong>courses at Talk Python Training</strong></a></li> <li><a href="https://courses.pythontest.com/p/the-complete-pytest-course?featured_on=pythonbytes"><strong>The Complete pytest Course</strong></a></li> <li><a href="https://www.patreon.com/pythonbytes"><strong>Patreon Supporters</strong></a> <strong>Connect with the hosts</strong></li> <li>Michael: <a href="https://fosstodon.org/@mkennedy">@mkennedy@fosstodon.org</a> / <a href="https://bsky.app/profile/mkennedy.codes?featured_on=pythonbytes">@mkennedy.codes</a> (bsky)</li> <li>Brian: <a href="https://fosstodon.org/@brianokken">@brianokken@fosstodon.org</a> / <a href="https://bsky.app/profile/brianokken.bsky.social?featured_on=pythonbytes">@brianokken.bsky.social</a></li> <li>Show: <a href="https://fosstodon.org/@pythonbytes">@pythonbytes@fosstodon.org</a> / <a href="https://bsky.app/profile/pythonbytes.fm">@pythonbytes.fm</a> (bsky) Join us on YouTube at <a href="https://pythonbytes.fm/stream/live"><strong>pythonbytes.fm/live</strong></a> to be part of the audience. Usually <strong>Monday</strong> at 11am PT. Older video versions available there too. Finally, if you want an artisanal, hand-crafted digest of every week of the show notes in email form? Add your name and email to <a href="https://pythonbytes.fm/friends-of-the-show">our friends of the show list</a>, we'll never share it.</li> </ul> <p><strong>Brian #1: <a href="https://www.better-simple.com/django/2026/05/06/using-django-tasks-in-production/?featured_on=pythonbytes">Using Django Tasks in production</a></strong></p> <ul> <li>Tim Schilling shares how the Djangonaut Space website has been using Django’s new tasks framework and some of the info missing from the official Django docs.</li> <li>Tasks require a third party package, <a href="https://github.com/RealOrangeOne/django-tasks-db?featured_on=pythonbytes"><code>django-tasks-db</code></a> to actually run the tasks.</li> <li>Article walks through all changes necessary to get an email process running to notify admins of new testimonials. Cool simple example.</li> <li>With the db backend, you can monitor progress of tasks in the admin, to see which tasks are scheduled, completed, or have errors.</li> <li>Some wishes for the community to implement <ul> <li>new tutorial in the Django docs</li> <li>Django Debug toolbar panel for tasks</li> <li>test/mock backend</li> </ul></li> <li>Great title for wish list: Thinks I’d like to see, but I’m too lazy to implement myself.</li> </ul> <p><strong>Michael #2: Co-authored with Claude?</strong></p> <ul> <li>Via Nik T.</li> <li>We don’t put “executed on macOS”, “edited with PyCharm”, etc. in our commits. Why Claude?</li> <li>Seems like a growth hack to me, that I don’t really care to participate in.</li> <li>Some projects that have formalized their thoughts on this: <a href="https://redmonk.com/kholterhoff/2026/02/26/generative-ai-policy-landscape-in-open-source/?featured_on=pythonbytes">The Generative AI Policy Landscape in Open Source</a></li> <li>Adjust to turn off in <code>~/.claude/settings.json</code> see <a href="https://code.claude.com/docs/en/settings#attribution-settings">the docs</a>. <div class="codehilite"> <pre><span></span><code><span class="p">{</span> <span class="w"> </span><span class="nt">&quot;attribution&quot;</span><span class="p">:</span><span class="w"> </span><span class="p">{</span> <span class="w"> </span><span class="nt">&quot;commit&quot;</span><span class="p">:</span><span class="w"> </span><span class="s2">&quot;&quot;</span><span class="p">,</span> <span class="w"> </span><span class="nt">&quot;pr&quot;</span><span class="p">:</span><span class="w"> </span><span class="s2">&quot;&quot;</span> <span class="w"> </span><span class="p">}</span> <span class="p">}</span> </code></pre> </div></li> </ul> <p><strong>Brian #3: <a href="https://rushter.com/blog/pypi-packages/?featured_on=pythonbytes">PyPI packages are increasing rapidly</a></strong></p> <ul> <li>Artem Golubin</li> <li>There’s been an increase of published packages per week on PyPI</li> <li>A pretty big increase in the last handful of months.</li> <li>30% increase since 2025, clearly due to AI</li> <li>Artem is building <a href="https://github.com/rushter/hexora?featured_on=pythonbytes">hexora</a>, a malicious Python code detector.</li> <li>Cool package too, it can: <ul> <li>Audit project dependencies to catch potential supply-chain attacks</li> <li>Detect malicious scripts found on platforms like Pastebin, GitHub, or open directories</li> <li>Analyze IoC files from past security incidents</li> <li>Audit new packages uploaded to PyPi.</li> </ul></li> <li>Artem is using hexora to analyze recently published pypi packages and many are obviously vibecoded and trigger false positives for abuses of <code>eval</code>, <code>exec</code>, and <code>subprocess</code> <ul> <li>Side note: I don’t think that’s necessarily a false positive. Not malicious, but maybe a stupid-code-detector?</li> </ul></li> <li>Lots are LLM related, Lots have bots contributing code</li> <li>Publishing rate is crazy, dozens to hundreds of published versions in a day is a bug, not a feature</li> <li>Brian’s proposal, PyPI should limit releases per day for any package to something a sane human would do, even if they make a mistake on a release, to maybe like 2-3, definitely under 10, in a day. And if the repo has obvious agent contributors listed, maybe lower to the limit to 1-2 a day? Honestly, “move fast and break things” doesn’t apply to breaking the commons.</li> </ul> <p><strong>Michael #4: <a href="https://tildeweb.nl/~michiel/httpx2.html?featured_on=pythonbytes">httpx2</a></strong></p> <ul> <li>More on the httpx, httpxyz, etc changes: Pydantic people started their own fork, <a href="https://github.com/pydantic/httpx2?featured_on=pythonbytes">httpx2</a>.</li> <li>Michiel says “while we think httpxyz was definitely needed, we welcome httpx2 and think it should be the ‘blessed’ fork.”</li> <li>Kludex, who is among other things maintainer of Starlette, was considering a fork</li> <li>As it stands, httpx2 is lacking the performance improvements they added to httpxyz. But it will not be long before they will add those, too.</li> <li>Also they already made some smart decisions: <ul> <li>they are switching from certifi to <a href="https://github.com/pydantic/httpx2/pull/209?featured_on=pythonbytes">truststore</a></li> <li>they are switching to <a href="https://github.com/pydantic/httpx2/pull/933?featured_on=pythonbytes">compression.zstd</a> on Python 3.14+, enabling zstd compression by default</li> <li>they <a href="https://github.com/pydantic/httpx2/commit/160c7f59d7942efe0133516c161d39139780eb45?featured_on=pythonbytes">merged httpcore</a> and vendored it in their repository</li> </ul></li> <li><a href="https://news.ycombinator.com/item?id=48127570&featured_on=pythonbytes">Discussion on Hacker News</a></li> </ul> <p><strong>Extras</strong></p> <p>Brian:</p> <ul> <li><a href="https://anarc.at/blog/2026-05-16-four-horsemen/?featured_on=pythonbytes">The Four Horsemen of the LLM Apocalypse</a> - Anarcat</li> <li><a href="https://www.djangoproject.com/weblog/2026/may/12/2026-django-developers-survey/?featured_on=pythonbytes">Django/JetBrains 2026 developer survey</a> is open</li> <li><a href="https://pyrefly.org/blog/v1.0/?featured_on=pythonbytes">Pyrefly 1.0</a> : “meaning we are confident that Pyrefly is ready for production use.” Michael:</li> <li>Just about ready to release Python Web Security: OWASP Top 10 with Agentic AI course. Be sure to be on <a href="https://training.talkpython.fm/getnotified?featured_on=pythonbytes">the courses newsletter</a> to get notified.</li> </ul> <p><strong>Joke:</strong> <a href="https://x.com/PR0GRAMMERHUM0R/status/1973145866962665752?featured_on=pythonbytes">Proud Parents</a></p>

May 18, 2026 08:00 AM UTC

Core Dispatch

Core Dispatch #4

Welcome back to Core Dispatch! This edition covers April 30 through May 18, 2026. Python 3.15.0 beta 1 is officially here, which means CPython's main branch is now open for 3.16 work. The first 3.16 alpha is slated for mid-October. More imminently, beta 2 is up next on June 2, with 3.13.14 and 3.14.6 following on June 9.

This is also PyCon US week, so a lot of the core team is gathered in Long Beach right now. Once recordings are available, we'll be sure to pull talks from folks on the team into a future edition.

PEP 788 has also moved from accepted to implemented, and free-threaded builds picked up thread-safe iterator support. There are also a few smaller but concrete fixes: http.server can send custom headers from the command line, AttributeError can suggest Python equivalents for method names from other languages, webbrowser on macOS is moving away from osascript, and ftplib.ftpcp() picked up the PASV CVE fix.

If you maintain a package or just like living on the edge, give the latest 3.15 beta a spin and file any issues you find.

Upcoming Releases

• Python 3.15.0 beta 2 — Jun 02
• Python 3.13.14 — Jun 09
• Python 3.14.6 — Jun 09

Official News

• Python 3.14.5 is out! — By Hugo van Kemenade
• Python 3.15.0 beta 1 is here! — By Hugo van Kemenade
• Python 3.14.5 release candidate — By Hugo van Kemenade

Merged PRs

• Add a --header CLI argument to http.server
• Add free-threading support for iterators
• Replace osascript with open on macOS in webbrowser
• Add Zd/Zf formats to array, ctypes, memoryview, struct
• Add cross-language method suggestions for builtin AttributeError
• Implement PEP 788
• Apply CVE-2021-4189 PASV fix to ftplib.ftpcp()

Discussion

• PEP 661: Sentinel Values — 🔥 32 new replies · 34.7k views
• PEP 832: Virtual Environment Discovery — 9 new replies · 4.2k views
• PEP 802: Display Syntax for the Empty Set — 6 new replies · 10.4k views
• PEP 828: Supporting yield from in asynchronous generators — 5 new replies · 3.3k views

Upcoming CFPs & Conferences

• PyCon Italia 2026 — May 27
• Python Leiden User Group — May 28
• 📋 Swiss Python Summit 2026 Deadline — May 31
• 📋 PyCon Indonesia 2026 Deadline — May 31
• 📋 PyCon Togo 2026 Deadline — Jun 01
• 📋 PyCon Ghana 2026 Deadline — Jun 06
• GeoPython 2026 — Jun 08
• 📋 PyCon Kenya 2026 Deadline — Jun 09
• 📋 PyCon South Korea 2026 Deadline (extended) — Jun 14
• 📋 Python Ho 2026 Deadline — Jun 15

One More Thing

"It's oompa loompa shit"

— Pablo Galindo Salgado

Credits

• Savannah Ostrowski
• Hugo van Kemenade
• Emma Smith

May 18, 2026 12:00 AM UTC

May 17, 2026

Artem Golubin

PyPI packages are increasing rapidly

PyPI is the main repository for Python packages. One thing that I've noticed recently is the number of published packages per week.

Let's look at published counts of new package versions per week:

There are some dips in the data, but that's because of how the data was collected. We can see a clear increase in the number of published packages, especially in the last few months.

Because of AI, the number of packages published per week has increased by 30% since 2025.

I'm working on hexora, a library that detects malicious Python code in packages.[......]

May 17, 2026 01:37 PM UTC

May 16, 2026

PyCon

Welcome Back, NVIDIA: Visionary Sponsor of PyCon US 2026

NVIDIA is excited to once again support PyCon US 2026 as a Visionary Sponsor, and to sponsor the Future of AI with Python Conference Track.

Python is a “first-class” language at NVIDIA CUDA, and NVIDIA is committed to bringing our technology to Python developers in close alignment with C++ upon new releases of our hardware. We’re also happy to announce the general availability of CUDA Python 1.0.

NVIDIA’s commitment to Python goes well beyond just our own tech stack. NVIDIA’s Python engineers contribute across a broad swath of the Python ecosystem, from the core interpreter itself, to packaging and PyPI, to the Python community at large. NVIDIA is inspired by the energy of, and privileged to collaborate with, people across the open source Python community.

Since PyCon last year, NVIDIA Pythonistas – in collaboration with many others in the Python community – have made great progress on the evolution of various packaging standards, including working with community partners on the implementation of wheel variants and the establishment of a Packaging Council to better govern the evolution of packaging standards and PyPI. NVIDIA Python engineers are also engaged in implementation, testing, and porting work for the free-threaded build of the interpreter. NVIDIA Python engineers are driving the early exploratory work for adopting Rust for CPython, work on Python performance benchmarking, and are actively involved in many enhancements for Python 3.14 and 3.15, including providing built-in Zstandard support in Python 3.14.

At NVIDIA, we are excited to work with our partners and the open source Python community to help bring the best developer experience for users of high performance computing and AI. Come see NVIDIA at the Anaconda and PyTorch booths, and at the AI Track.

Barry Warsaw
May 2026
Principal System Software Engineer, NVIDIA
Python Core Developer since 1994
Python Steering Council member in 2026

May 16, 2026 02:30 PM UTC

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