> These things are average text generation machines.

Funny... seems like about half of devs think AI writes good code, and half think it doesn't. When you consider that it is designed to replicate average output, that makes a lot of sense.

So, as insulting as OP's idea is, it would make sense that below-average devs are getting gains by using AI, and above-average devs aren't. In theory, this situation should raise the average output quality, but only if the training corpus isn't poisoned with AI output.

I have an anecdote that doesn't mean much on its own, but supports OP's thesis: there are two former coworkers in my linkedin feed who are heavy AI evangelists, and have drifted over the years from software engineering into senior business development roles at AI startups. Both of them are unquestionably in the top 5 worst coders I have ever worked with in 15 years, one of them having been fired for code quality and testing practices. Their coding ability, transition to less technical roles, and extremely vocal support for the power of vibe coding definitely would align with OP's uncharitable character evaluation.

> it would make sense that below-average devs are getting gains by using AI

They are certainly opening more PRs. Being the gate and last safety check on the PRs is certainly driving me in the opposite direction.

After a certain experience level though, I think most of us get to the point of knowing what that difference in quality actually matters.

Some seniors love to bikeshed PRs all day because they can do it better but generally that activity has zero actual value. Sometimes it matters, often it doesn't.

Stop with the "I could do this better by hand" and ask "is it worth the extra 4 hours to do this by hand, or is this actually good enough to meet the goals?"

LLM generated code is technical debt. If you are still working on the codebase the next day it will bite you. It might be as simple as an inconvenient interface, a bunch of duplicated functions that could just be imported, but eventually you are going to have to pay it.

All code is technical debt though. We can't spend infinite hours finding the absolute minima of technical debt introduced for a change, so it is just finding the right balance. That balance is highly dependent on a huge amount of factors: how core is the system, what is the system used for, what stage of development is the system, etc.

I spend about half my day working on LLM-generated code and half my day working on non-LLM-generated code, some written by senior devs, some written by juniors.

The LLM-generated code is by far the worst technical debt. And a fair bit of that time is spent debugging subtle issues where it doesn't quite do what was prompted.

Untested undocumented LLM code is technical debt, but if you do specs and tests it's actually the opposite, you can go beyond technical debt and regenerate your code as you like. You just need testing to be so good it guarantees the behavior you care about, and that is easier in our age of AI coding agents.

> but if you do specs and tests it's actually the opposite, you can go beyond technical debt and regenerate your code as you like.

Having to write all the specs and tests just right so you can regenerate the code until you get the desired output just sounds like an expensive version of the infinite monkey theorem, but with LLMs instead of monkeys.

You can have it write the specs and tests, too, and review and refine them much faster than you could write them.

... so you hand-write the specs and tests?

I use LLMs to generate tests as well, but sometimes the tests are also buggy. As any competent dev knows, writing high-quality tests generally takes more time than writing the original code.

In your comment replace “LLM” with “Human SWE” and statement will still be correct in vast majority of the situations :)

That's legit true. All code is technical debt. Human SWEs have one saving grace. Sometimes they refactor and reduce some of the debt.

A human SWE can use an LLM to refactor and reduce some of the debt just as easily too. I think fundamentally, the possible rate of new code and new technical debt introduced by LLMs is much higher than a human SWE. Left unchecked, a human still needs sleep and more humans can't be added with more compute.

There's an interesting aspect to the LLM debt being taken on though in that I'm sure some are taking it on now in the bet/hopes that further advancements in LLMs will make it more easily addressable in the future before it is a real problem.

Are people not reviewing and refactoring LLM code?

"actually good enough to meet the goals?"

There's "okay for now" and then there's "this is so crap that if we set our bar this low we'll be knee deep in tech debt in a month".

A lot of LLM output in the specific areas _I_ work in is firmly in that latter category and many times just doesn't work.

Yes if I went hard on something greenfield I'm sure I'll be knee deep in tech debt in less than a day.

That being said, given the quality of code these things produce, I just don't see that ever stopping being the case. These things require a lot of supervision and at some point you are spending more time asking for revisions than just writing it yourself.

There's a world of difference between an MPV which, in the right domain, you can get done much faster now, and a finished product.

I think you missed the your parent post's phrase "in the specific areas _I_ work in" ... LLMs are a lot better at crud and boilerplate than novel hardware interfaces and a bunch of other domains.

But why would it take a month to generate significant tech debt in novel domains, it would accrue even faster then right? The main idea I wanted to get across is that iteration speed is much faster so what's "tech debt" in the first pass, can be addressed much faster in future passes, which will happen on the order of days rather than sprints in the older paradigm. Yes the first iterations will have a bunch of issues but if you keep your hands on the controller you can get things to a decent state quickly. I think one of the biggest gaps I see in devs using these tools is what they do after the first pass.

Also, even for novel domains, using tools like deep research and the ability of these tools to straight up search through the internet, including public repos during the planning phase (you should be planning first before implementing right? You're not just opening a window and asking in a few sentences for a vaguely defined final product I hope) is a huge level up.

If there are repos, papers, articles, etc of your novel domain out there, there's a path to a successful research -> plan -> implement -> iterate path out there imo, especially when you get better at giving the tools ways to evaluate their own results, rather than going back and forth yourself for hours telling them "no, this part is wrong, no now this part is wrong, etc etc"

I mean, there's also, "this looks fine but if I actually had written this code I would've naturally spent more time on it which would have led me to anticipate the future of this code just a little bit more and I will only feel that awkwardness when I come back to this code in two weeks, and then we'll do it all over again". It's a spectrum.

Right.

And greenfield code is some of the most enjoyable to write, yet apparently we should let robots do the thing we enjoy the most, and reserve the most miserable tasks for humans, since the robots appear to be unable to do this.

I have yet to see an LLM or coding agent that can be prompted with "Please fix subtle bugs" or "Please retire this technical debt as described in issue #6712."

If you're willing to purchase enough tokens, you can prompt and agent to loop and fuzz its way to "retire* this technical debt as described in issue #6712". But then you still need to review it and make sure it's not just doing a "debt-swap", like some kind of metaverse financial swindler. So you're spending money to avoid fixing tech debt, but adding in the need to review "someone else's code". And to take ownership of that code!

*(Of course, depending on the issue, it could be doing anything from surpressing logs so existing tests pass, to making useless-but-passing tests, to brute-forcing special cases, to possibly actually fixing something.)

Perhaps writing code by hand will be considered micro optimisation in the future.

Just like writing assembly is today.

I think this is an opportunity for that bell curve/enlightenment meme. Of course as you get a little past junior, you often get hung up on the best way of doing things without worrying about best being the enemy of good enough. But truly senior devs know the difference. And those are the ones that by and large still think LLMs are bad at generating code where quality (reliability, sustainability, security, etc) matters. Everyone admits that LLMs are good for low stakes code.

now sometimes that's 4 hours, but I've had plenty of times where I'm "racing" people using LLMs and I basically get the coding done before them. Once I debugged an issue before the robot was done `ls`-ing the codebase!

The shape of the problem is super important in considering the results here

You have the upper hand with familiarity of the code base. Any "domain expert" also necessarily has a head start knowing which parts of a bespoke complex system need adjustment when making changes.

On the other hand, a highly skilled worker who just joined the team won't have any of that tribal knowledge. There is a significant lag time getting ramped up, no matter how intelligent they are due to sheer scale (and complexity doesn't help).

A general purpose model is more like the latter than the former. It would be interesting to compare how a model fine tuned on the specific shape of your code base and problem domain performs.

People usually talk about how they're better than LLMs in the domains they're experts and with known codebases.

What about all the other, large amounts of cases? Don't you ever face situations in which an LLM can greatly help (and outrace) you?

Yeah totally, for unknown codebases it can help kick you off in the right direction (though it can send you down a totally wrong path as well... projects with good docs tend to be ones where I've found LLMs be worse at their job on this ironically).

But well.. when working with coworkers on known projects it's a different story, right?

My stance is these tools are, of course, useful, but humans can most definitely be faster than the current iteration of these tools in a good number of tasks, and some form of debugging tasks are like that for me. The ones I've tried have been too prone to meandering and trying too many "top results on Google"-style fixes.

But hey maybe I'm just holding it wrong! Just seems like some of my coworkers are too

I worked for a relatively large company (around 400 employees there are programmers). The people who embraced LLM-generated code clearly share one trait: they are feature pushers who love to say "yes!" to management. You see, management is always right, and these programmers are always so eager to put their requirements, however incomplete, into a Copilot session and open a pull request as fast as possible.

The worst case I remember happened a few months ago when a staff (!) engineer gave a presentation about benchmarks they had done between Java and Kotlin concurrency tools and how to write concurrent code. There was a very large and strange difference in performance favoring Kotlin that didn't make sense. When I dug into their code, it was clear everything had been generated by a LLM (lots of comments with emojis, for example) and the Java code was just wrong.

The competent programmers I've seen there use LLMs to generate some shell scripts, small python automations or to explore ideas. Most of the time they are unimpressed by these tools.

I've been playing with vibe coding a lot lately and I think in most cases, the current SOTA LLM's don't produce code that I'd be satisfied with. I kind of feel like LLM's are really really good at hacking on a messy and fragile structure, because they can "keep track many things in their head"

BUT

An LLM can write a PNG decoder that works in whatever language I choose in one or a few shots. I can do that too, but it will take me longer than a minute!

(and I might learn something about the png format that might be useful later..)

Also, us engineers can talk about code quality all day, but does this really matter to non-engineers? Maybe objectively it does, but can we convince them that it does?

> Maybe objectively it does, but can we convince them that it does?

how long would you give our current civilisation if quality of software ceased to be important for:

  - medical devices
  - aircraft
  - railway signalling systems
  - engine management systems
  - the financial system
  - electrical grid
  - water treatment
  - and every other critical system

unless "AI" dies, we're going to find out

Yet it is rare someone ever needs to write a PNG decoder.

In the unlikely event you did, you would be doing something quite special to not be using an off-the-shelf library. Would an LLM be able to do whatever that special thing would be?

It's true that quality doesn't matter for code that doesn't matter. If you're writing code that isn't important, then quality can slip, and it's true an LLM is good candidate for generating that code.

I tried vibe coding a BMP decoder not too long ago with the rationale being “what’s simpler than BMP?”

What I got was an absolute mess that did not work at all. Perhaps this was because, in retrospect, BMP is not actually all that simple, a fact that I discovered when I did write a BMP decoder by hand. But I spent equal time vibe coding and real coding. At the end of the real coding session, I understood BMP, which I see as a benefit unto itself. This is perhaps a bit cynical but my hot take on vibe coders is that they place little value on understanding things.

Mind explaining the process you tried? As someone who’s generally not had any issue getting LLMs to sort out my side projects (ofc with my active involvement as well), I really wonder what people who report these results are trying. Did you just open a chat with claude code and try to get a single context window to one shot it?

Just out of curiousity (as someone fairly familiar with the BMP spec, and also PNG incidentally): what did you find to be the trickiest/most complex aspects?

None of this is fresh in my mind, so my recollections might be a little hazy. I think the only issue I personally had when writing a decoder was keeping the alignment of various fields right. I wrote the decoder in C# and if I remember correctly I tried to get fancy with some modern-ish deserialization code. I think I eventually resorted to writing a rather ugly but simple low-level byte reader. Nevertheless I found it to be a relatively straightforward program to write and I got most of what I wanted done in under a day.

The vibe coded version was a different story. For simplicity, I wanted to stick to an early version of BMP. I don’t remember the version off the top of my head. This was a simplified implementation for students to use and modify in a class setting. Sticking to early version BMPs also made it harder for students to go off-piste since random BMPs found on the internet probably would not work.

The main problem was that the LLM struggled to stick to a specific version of BMP. Some of those newer features (compression, color table, etc, if I recall correctly) have to be used in a coordinated way. The LLM made a real mess here, mixing and matching newer features with older ones. But I did not understand that this was the problem until I gave up and started writing things myself.

You should try a similar task with a recent model (Opus 4.5, GPT 5.2, etc) and see if there are any improvements since your last attempt. I also encourage using a coding agent. It can use test files that you provide, and perform compile-test loops to work out any mistakes.

It sounds like you used an older model, and perhaps copy-pasted code from a chat session. (Just guessing, based on what you described.)

I kinda like Theo's take on it (https://www.youtube.com/watch?v=Z9UxjmNF7b0): there's a sliding scale of how much slop should reasonably be considered acceptable and engineers are well advised to think about it more seriously. I'm less sold on the potential benefits (since some of the examples he's given are things that I would also find easy by hand), but I agree with the general principle that having the option to do things in a super-sloppy way, combined with spending time developing intuition around having that access (and what could be accomplished that way), can produce positive feedback loops.

In short: when you produce the PNG decoder, and are satisfied with it, it's because you don't have a good reason to care about the code quality.

> Maybe objectively it does, but can we convince them that it does?

I strongly doubt it, and that's why articles like TFA project quite a bit of concern for the future. If non-engineers end up accepting results from a low-quality, not-quite-correct system, that's on them. If those results compromise credentials, corrupt databases etc., not so much.

Claude Code is way better than I am at rummaging through Git history, handling merge conflicts, renaming things, writing SQL queries whose syntax I always forget (window functions and the like). But yeah. If I give it a big, non-specific task, it generates a lot of mediocre (or worse) code.

That's funny that's all the things I don't trust it to do. I actually use it the other way around, give it a big non-specific task, see if it works, specify better, retry, throw away 60% - 90% of the generated code, fix bugs in a bunch of places and out comes an implemented feature.

Agreed. Claude is horrible at munging git history and can destroy the thing I depend on to fix Claude's messes. I always do my git rebasing by hand.

The first iteration of Claude code is usually a big over-coded mess, but it's pretty good at iterating to clean it up, given proper instruction.

I give the agent the following standing instructions:

"Make the smallest possible change. Do not refactor existing code unless I explicitly ask."

That directive cut down considerably on the amount of extra changes I had to review. When it gets it right, the changes are close to the right size now.

The agent still tries to do too much, typically suggesting three tangents for every interaction.

As someone who: 1.) Has a brain that is not wired to think like a computer and write code. 2.) Falls asleep at the keyboard while writing code for more than an hour or two. 3.) Has a lot of passion for sticking with an idea and making it happen, even if that means writing code and knowing the code is crap.

So, in short, LLMs write better code than I do. I'm not alone.

You are defective. But, fear not! So is the rest of humanity!

LLMs are not "average text generation machines" once they have context. LLMs learn a distribution.

The moment you start the prompt with "You are an interactive CLI tool that helps users with software engineering at the level of a veteran expert" you have biased the LLM such that the tokens it produces are from a very non-average part of the distribution it's modeling.

True, but nuanced. The model does not react to "you are an experienced programmer" kinds of prompts. It reacts to being given relevant information that needs to be reflected in the output.

See examples in https://arxiv.org/abs/2305.14688; They certainly do say things like "You are a physicist specialized in atomic structure ...", but the important point is that the rest of the "expert persona" prompt _calls attention to key details_ that improves the response. The hint about electromagnetic forces in the expert persona prompt is what tipped off the model to mention it in the output.

Bringing attention to key details is what makes this work. A great tip for anyone who wants to micromanage code with an LLM is to include precise details about what they wish to micromanage: say "store it in a hash map keyed by unsigned integers" instead of letting the model decide which data structure to use.

It'd be rather surprising if you could train an AI on a bunch of average code, and somehow get code that's always above average. Where did the improvement come from?

We should feed the output code back in to get even better code.

AI generally can improve through reinforcement learning, but this requires it to be able to compare its output to some form of metric. There aren't a lot of people I'd trust to RLHF for code quality, and anything more automated than that is destined to collapse due to Goodhart's Law.

In my view they’re great for rough drafts, iterating on ideas, throwaway code, and pushing into areas I haven’t become proficient in yet. I think in a lot of cases they write ok enough tests.

How are you judging that you'd write "better" code? More maintainable? More efficient? Does it produce bugs in the underlying code it's generating? Genuinely curious where you see the current gaps.

For me the biggest gaps in LLM code are:

- it adds superfluous logic that is assumed but isn’t necessary

- as a result the code is more complex, verbose, harder to follow

- it doesn’t quite match the domain because it makes a bunch of assumptions that aren’t true in this particular domain

They’re things that can often be missed in a first pass look at the code but end up adding a lot of accidental complexity that bites you later.

When reading an unfamiliar code base we tend to assume that a certain bit of logic is there for a good reason, and that helps you understand what the system is trying to do. With generative codebases we can’t really assume that anymore unless the code has been thoroughly audited/reviewed/rewritten, at which point I find it’s easier to just write the code myself.

This has been my experience as well. But, these are things we developers care about.

Coding aside, LLM's aren't very good at following nice practices in general unless explicitly prompted to. For example if you ask an LLM to create an error modal box from scratch, will it also implement the ability to select the text, or being able to ctrl c to copy the text, or perhaps a copy message button? Maybe this is a bad example, but they usually don't do things like this unless you explicitly ask them to. I don't personally care too much about this, but I think it's noteworthy in the context of lay people using LLM's to vibe code.

I've seen a lot of examples where it fails to take advantage of previous work and rewrites functionality from scratch.

> if you’re seeing output that is consistently better than what you produce by hand, you’re probably just below average at programming

even though this statement does not mathematically / statistically make sense - vast majority of SWEs are “below average.” therein lies the crux of this debate. I’ve been coding since the 90’s and:

- LLM output is better than mine from the 90’s

- LLM output is better than mine from early 2000’s

- LLM output is worse than any of mine from 2010 onward

- LLM output (in the right hands) is better than 90% of human-written code I have seen (and I’ve seen a lot)

The most prolific coders are also more competent than average. Their proliferations are what have trained these models. These models are trained on incredibly successful projects written by masters of their fields. This is usually where I find the most pushback is that the most competent SWEs see it as theft and also useless to them since they have already spend years honing skills to work relentlessly and efficiently towards solutions -- sometimes at great expense.

> The most prolific coders are also more competent than average

This is absolutely not true lol, as anyone who's worked with a fabled 10X engineer will tell you. It's like saying the best civil engineer is the one that builds the most bridges.

The best code looks real boring.

I've worked with a 10x engineer and indeed they were significantly more competent than the rest of the team in their execution and design. They've seen so many problems and had a chance to discard bad patterns and adopt/try out new ones.

Nah, just better at marketing and coming up with plausible things that make them sound good. You learn to spot that type after a while. There are a rare few people who do get a lot done, but usually it's because they work 80 hour weeks.

I'd assume most of the code visible on the web leans amateur. A huge portion of github repos seem to be from students these days. You'll see GitHub's Education page listing "5 million students" (https://github.com/education), which I assume is an under-estimate, as that's only the formal program.

This has been my experience as well.

It's let me apply my general knowledge across domains, and do things in tech stacks or languages I don't know well. But that has also cost me hours debugging a solution I don't quite understand.

When working in my core stack though it's a nice force multiplier for routine changes.

>When working in my core stack though it's a nice force multiplier for routine changes.

what's your core stack?

> Hearing people on tech twitter say that LLMs always produce better code than they do by hand was pretty enlightening for me.

That's hilarious LLM code is always very bad. It's only merit is it occasionally works.

> LLMs can produce better code for languages and domains I’m not proficient in.

I am sure that's not true.

I think it says more about who's still on tech twitter vs. anything about the llm....

It seems true by construction. If you're not proficient in a language than the bar for "better than you" is necessarily lower.

If you are an experienced developer in general your code will in general be better than an LLMs even in languages you are not proficient. The LLM code might be more in keeping with the languages conventions but that does not make the code automatically superior. LLMs typically produce bad code in other dimensions.

Well said

I saw someone refer to it as future digital asbestos.

Asbestos is a miracle material with a serious and hard to really avoid downside.

It's so good that we are genuinely left with crappy options to replace it, and people have died in fires that could have been saved with the right application of asbestos.

Current AI hype is closer to the Radium craze back during the discovery of radioactivity. Yes it's a neat new thing that will have some interesting uses. No don't put it in everything and especially not in your food what are you doing oh my god!