On-device models are the future. Users prefer them. No privacy issues. No dealing with connectivity, tokens, or changes to vendors implementations. I have an app using Foundation Model, and it works great. I only wish I could backport it to pre macOS 26 versions.
Users don’t care about “privacy”. If they did, Meta and Alphabet wouldn’t be worth $1T+.
Users really don’t matter at all. The revenue for AI companies will be B2B where the user is not the customer - including coding agents. Most people don’t even use computers as their primary “computing device” and most people are buying crappy low end Android phones - no I’m not saying all Android phones are crappy. But that’s what most people are buying with the average selling price of an Android phone being $300.
I worked for a research focused AI startup that had a strict "no external LLM" policy for code touching our core research.
You're right that the average consumer doesn't care about privacy, but there are many, many users who do. The average consumer also don't have a desktop with GPU or high end Mac Studio, but that doesn't mean there aren't many people working with AI how do have these things.
If we continue to see improvements in running local models, and RAM prices continue to fall as they have in the last month, then suddenly you don't have to worry about token counts any more and can be much more trusting of your agents since they are fully under your control.
Those users are addressed by being able to rent their own exclusive machines to run the model on. There will be some compromise that will be made to get access to the best intelligence available.
Different users. Many people care about privacy and aren’t using Meta products. And many businesses care about it too and have information policies to protect their IP.
> Different users. Many people care about privacy and aren’t using Meta products.
Yeah but if they can rake in 100x as much by making products for people who don't care about privacy, then why spend time developing stuff for people who care?
There is still a small market left, of course, but that market will not have the billions of R&D behind it.
It's largely out of Meta's hands now anyway. The risk here not so much to privacy (it's Apple) but they'll walled garden the model space somehow for sure.
70% of the world’s population use at least one Meta property at least once per day. How many of the other 30% are too poor/young/computer illiterate to be part of an addressable market?
Every company has dozens of SaaS products that store their business critical information. Amazon installs Office on each computer, Slack (they were moving away from Chime when I left), and the sales department uses SalesForce - SA’s and Professional Services (former employee).
The addressable market of even companies that care about privacy is not a large addressable market. How long will it be before computers become cheap enough that can run even GPT 4 level LLMs that companies will give it to all of their developers?
The banking industry absolutely does care about privacy of their business data btw.
We do use tools like Confluence but they're all hosted in our own data centers.
These are all great statistics, but how do you explain ClawdBot explosion. Even in lower income countries like China. So much demand that Apple can’t keep up production of Mac Minis. Why aren’t these folks going towards cloud solutions? Is it cost or is there some consideration for having more control over their data?
ClawBot doesn't generally run the model locally, it just talks to remote APIs. No different than any other agentic harness. You could run a local model on the same Mac Mini as your agent, but it wouldn't be very smart and many agentic tasks around computer GUI/browser use, etc. would be out of reach.
They are running cloud models in almost all cases. Like saying it isn’t cloud when you use the Facebook app on your phone (it is ON your phone and running there).
> Why aren’t these folks going towards cloud solutions?
They are. The majority aren't doing inference on a Mac Mini, but instead using it as a local host for cloud-based inference. You could have the same general experience on a $200 Chromebook or $300 Windows box.
I see it as a long-term tradeoff on user freedom.
You pay upfront for a capable hardware, you get your services running locally (you don’t pay subscriptions).
Or you buy cheap hardware, you still need the same services “running in some cloud” for $X monthly. X goes up depending on the corporate bottom-line
In the history of cloud computing, prices have mostly only come down especially as inference becomes a commodity. Realistically, just looking at Mac prices, the cost of a computer with decent local inference would be around $6000 per person.
> Realistically, just looking at Mac prices, the cost of a computer with decent local inference would be around $6000 per person.
As someone who has hardware in that price range and plays with local LLMs: The gap between Opus or GPT and the local models is still very large for work beyond simple queries.
Self-hosted also starts making my office hot due to all of the power consumption when I use it for anything more than short queries. If you haven't heard your Mac's fans spin up much yet, running local LLMs will get you acquainted with the sound of their cooling systems at full blast.
Your customers are an anecdote, now compare that to the publicly reported numbers from AWS, GCP and Azure where they all say the only thing keeping them from growing more is the chip shortage.
Oh I'm sure they'll continue to have some cloud services, no doubt. But look at VMware for example, even after the insane price increases. Nutanix also seems to be doing quite well. I'm seeing a fair amount of on-prem bare metal k8s too.
Again - anecdotes is not data. We have data. That would be about as silly as me citing my own experience as proof that “everyone is moving to AWS” when I work for a company that is exclusively an AWS partner consulting company.
User's care about privacy when they understand the threat and impact. The issue is most user's don't understand this, especially when it comes to use of products like Meta where on the surface, everything appears harmless.
Have you done A/B tests to see if consumers prefer Facebook with or without privacy?
No? What? Oh, you can't?
Neither can consumers. Most consumers are very aware of the lack of privacy, the manipulation, and have very cynical feelings about Facebook and similar companies. But it's where their friends and family are.
For most people the web is a mine field maze where basic things they want are compromised everywhere. And they are routinely creeped out by ads that reveal they know them far too personally.
You are mistaking network capture for preference.
Another telling example. Lots of privacy valuing technical people, who would never have a Facebook account, send unencrypted text emails.
Consumers pro actively tell Facebook their age, sexual preference, race, relationship status, likes and dislikes, they check in to where they are and who they are there with…
Yes, they do. That's is exactly the phenomena my comment addressed.
But the way you wrote that implies an improbable motivation or choice framing.
Perhaps their real motive/choice is to share with other people on the site.
It is called a network effect.
If (1) Facebook had been the surveillance/manipulation capital of the world from inception, (2) an equally inviting privacy protecting site took off at the same time, and (3) everyone chose Facebook over E2EE anyway, then sure, we could throw up our hands! Those silly users!
The term I have for when people discuss choices involving many-dimensional criteria, as if the choice involved just one or two selected dimensions, is "dimension blindness". It happens in a lot of heated discussions about phone choices too.
Wouldn’t the most obvious way for people to protect their privacy while using FB if they cared and still wanted to use FB be not to proactively give them information? You don’t have to share everything I mentioned just to be involved in a group.
It’s not all or nothing there ads trade offs. The fact that Apple still bothers to expend marketing effort on its privacy chops suggests significant numbers of people still do care.
Users here probably means corporations. I still don’t see much use of LLMs in my personal life, other than one thing. Googling stuff in a foreign language.
"Users" is a large set of people. Many don't care about privacy, but some do. There's also a difference between where you post random social media stuff vs what you run with something like OpenClaw and give access to your machine.
you are missing a but 'given a choice' disclaimer. Meta is pretty much a monopoly in social space. So is Android. given a choice people will absolutely gravitate towards not-always-snooping device. most people with resources anyway, who matter for the AI adoption.
Oh an wait till ad companies start selling your healthcare data and you will see how fast things turn 'given a choice'.
People don't have a choice between Facebook and not-Facebook-but-still-has-all-of-your-friends-and-family. Abstinence isn't a choice here any more than shutting off your cell phone service is a choice; true in the literal sense, but only if you don't mind being unreachable to everyone who still has a phone.
I think two recent advances make your statement more true. The new Qwen 3.5 series has shown a relatively high intelligence density, and Google's new turboquant could result in dramatically smaller/efficient models without the normal quantization accuracy tradeoff.
I would expect consumer inference ASIC chips will emerge when model developments start plateauing, and "baking" a highly capable and dense model to a chip makes economic sense.
Who will be funding state of the art local models going forward? AI models are never done or good enough. They will have to be trained on new data and eventually with new model architectures. It will remain an expensive exercise.
I could be wrong because I'm not following this too closely, but the open weights future of both Llama and Qwen looks tenuous to me. Yes, there are others, but I don't understand the business model.
Yes, but you don’t always want the power/expense of these models for the task at hand. A hammer is good enough to push a nail inside a wall. Save the nail gun for when you are building a house.
Yes so far do we have a working practice that, with a given local mode, any infra we could use, that provide a good practice that can leverage it for local task?
most of the llm tooling can handle different models. Ollama makes it easy to install and run different models locally. So you can configure aider or vscode or whatever you're using to connect to chatgpt to point to your local models instead.
None of them are as good as the big hosted models, but you might be surprised at how capable they are. I like running things locally when I can, and I also like not worrying about accidentally burning through tokens.
I think the future is multiple locally run models that call out to hosted models when necessary. I can imagine every device coming with a base model and using loras to learn about the users needs. With companies and maybe even households having their own shared models that do heavier lifting. while companies like openai and anhtropic continue to host the most powerful and expensive options.
What models have you found capable? I was recently recommended Qwen3 Coder Next and I did not find it very successful. I have a good amount of VRAM/RAM so would love to run something locally.
I created "apfel" https://github.com/Arthur-Ficial/apfel a CLI for the apple on-device local foundation model (Apple intelligence) yeah its super limited with its 4k context window and super common false positives guardrails (just ask it to describe a color) ... bit still ... using it in bash scripts that just work without calling home / out or incurring extra costs feels super powerful.
Neat! I’ve actually been building with AFM, including training some LoRA adapters to help steer the model. With the right feedback mechanisms and guardrails, you can even use it for code generation! Hopefully I’ll have a few apps and tools out soon using AFM. I think embedded AI is the future, and in the next few years more platforms will come around to AI as a local API call, not an authorized HTTP request. That said, AFM is still incredibly premature and I’m experimenting with newer models that perform much better.
Honestly I can't believe Apple put that foundation model product out the door. I was so excited about it, but when I tried it, it was such a disappointment. Glad to hear you calling that out so I know it wasn't just me.
Looks like they have pivoted completely over to Gemini, thank god.
This really makes me think of A Deepness in the Sky by Vernor Vinge. A loose prequel to A Fire Upon The Deep, and IMO actually the superior story. It plays in the far future of humanity.
In part of it, one group tries to take control of a huge ship from another group. They in part do this by trying to bypass all the cybersecurity. But in those far future days, you don't interface with all the aeons of layers of command protocols anymore, you just query an AI who does it for you. So, this group has a few tech guys that try the bypass by using the old command protocols directly (in a way the same thing like the iOS exploit that used a vulnerability in a PostScript font library from 90s).
Imagine being used to LLM prompting + responses, and suddenly you have to deal with something like
sed '/^```/d;/^#/d;s/^[[:space:]]\*//;/^$/d' | head -1); [[ $r ]]
and generally obtuse terminal output and man pages.
:)
(offtopic: name your variables, don't do local x c r a;. Readability is king, and a few hundred thousand years from now some poor Qeng Ho fellow might thank his lucky stars you did).
LLMs on device is the future. It's more secure and solves the problem of too much demand for inference compared to data center supply, it also would use less electricity. It's just a matter of getting the performance good enough. Most users don't need frontier model performance.
> False, it creates consumer demand for inference chips, which will be badly utilised.
I think the opposite is true. Local inference doesn't have to go over the wire and through a bunch of firewalls and what have you. The performance from just regular consumer hardware with local, smaller models is already decent. You're utilizing the hardware you already have.
> The performance limitations are inherent to the limited compute and memory.
When you plug in a local LLM and inference engine into an agent that is built around the assumption of using a cloud/frontier model then that's true.
But agents can be built around local assumptions and more specific workflows and problems. That also includes the model orchestration and model choice per task (or even tool).
The Jevons Paradox comes into play with using cloud models. But when you have less resources you are forced to move into more deterministic workflows. That includes tighter control over what the agent can do at any point in time, but also per project/session workflows where you generate intermediate programs/scripts instead of letting the agent just do what ever it wants.
I give you an example:
When you ask a cloud based agent to do something and it wants more information, it will often do a series of tool calls to gather what it thinks it needs before proceeding. Very often you can front load that part, by first writing a testable program that gathers most of the necessary information up front and only then moving into an agentic workflow.
This approach can produce a bunch of .json, .md files or it can move things into a structured database or you can use embeddings or what have you.
This can save you a lot of inference, make things more reusable and you don't need a model that is as capable if its context is already available and tailored to a specific task.
Parallel inference on large compute scales in superlinear ways. There is no way to beat the reduction in memory transfers that a data-center inference model provides with hardware that fits at anything called a home. It is much more energy efficient to process huge batches of parallel requests compared to having one or a handful of queries running on an accelerator.
Aren't data centers extremely energy inneficient due to network latency, memory bottlenecks and so on? I mean the models that run on them are extremely powerful compared to what you can run on consumer hardware, but I wouldn't call them efficient...
I'm sorry to get into this conversation, but the performance of a model is some orders of magnitude lower (meaning it requires greater amounts of specific computing power) than all the network stack of all the nodes involved in the internet traffic of some particular request.
Meaning: these 5000 tokens consume tiny amounts of energy being moved all around from the data center to your PC, but enormous amounts of energy being generated at all. An equivalent webpage with the same amount of text as these tokens would be perceived as instant in any network configuration. Just some kilobytes of text. Much smaller than most background graphics. The two things can't be compared at all.
However, just last week there have been huge improvements on the hardware required to run some particular models, thanks to some very clever quantisation. This lowers the memory required 6x in our home hardware, which is great.
In the end, we spent more energy playing videogames during the last two decades, than all this AI craze, and it was never a problem. We surely can run models locally, and heat our homes in winter.
> False, it creates consumer demand for inference chips, which will be badly utilised.
There are so many CPUs, GPUs, RAM and SSDs which are underutilized. I have some in my closet doing 5% load at peek times. Why would inference chips be special once they become commodity hardware?
The fact that today's and yesterday's models are quite capable of handling mundane tasks, and even companies behind frontier models are investing heavily in strategies to manage context instead of blindly plowing through problems with brute-force generalist models.
But let's flip this around: what on earth even suggests to you that most users need frontier models?
Everybody has difficult decisions to make in their daily lives and in their work.
Having access to a model that is drawing from good sources and takes time to think instead of hallucinating a response is important in many domains of life.
While not everybody is a professional in YOUR domain, many people are professionals in SOME domain. And even outside of that, they deserve a smart conversation partner, for example on topics like health and politics.
I very recently installed llama.cpp on my consumer-grade M4 MBP, and I've been having loads of fun poking and prodding the local models. There's now a ChatGPT style interface baked into llama.cpp, which is very handy for quick experimentation. (I'm not entirely sure what Ollama would get me that llama.cpp doesn't, happy to hear suggestions!)
There are some surprisingly decent models that happily fit even into a mere 16 gigs of RAM. The recent Qwen 3.5 9B model is pretty good, though it did trip all over itself to avoid telling me what happened on Tiananmen Square in 1989. (But then I tried something called "Qwen3.5-9B-Uncensored-HauhauCS-Aggressive", which veers so hard the other way that it will happily write up a detailed plan for your upcoming invasion of Belgium, so I guess it all balances out?)
That's very cool! I think giving it some research tools might be a nifty thing to try next. This is a fairly new area for me, so pointers or suggestions are welcome, even basic ones. :)
Worth adding that I had reasoning on for the Tiananmen question, so I could see the prep for the answer, and it had a pretty strong current of "This is a sensitive question to PRC authorities and I must not answer, or even hint at an answer". I'm not sure if a research tool would be sufficient to overcome that censorship, though I guess I'll find out!
I'd recommend it too, because the knowledge cutoff of all the open weight Chinese models (M2.7, Qwen3.5, GLM-5 etc) is earlier than you'd think, so giving it web search (I use `ddgr` with a skill) helps a surprising amount
Yep, having a "stupid" central model with multiple tools is IMO the key to efficient agentic systems.
It needs to be just smart enough to use the tools and distill the responses into something usable. And one of the tools can be "ask claude/codex/gemini" so the local model itself doesn't actually need to do much.
> Yep, having a "stupid" central model with multiple tools is IMO the key to efficient agentic systems.
That doesn't fix the "you don't know what you don't know" problem which is huge with smaller models. A bigger model with more world knowledge really is a lot smarter in practice, though at a huge cost in efficiency.
Ive always wondered where the inflection point lies between on the one hand trying to train the model on all kinds of data such as Wikipedia/encyclopedia, versus in the system prompt pointing to your local versions of those data sources, perhaps even through a search like api/tool.
Is there already some research or experimentation done into this area?
The training gives you a very lossy version of the original data (the smaller the model, the lossier it is; very small models will ultimately output gibberish and word salad that only loosely makes some sort of sense) but it's the right format for generalization. So you actually want both, they're highly complementary.
MLX is faster because it has better integration with Apple hardware. On the other hand GGUF is a far more popular format so there will be more programs and model variety.
So its kinda like having a very specific diet that you swear is better for you but you can only order food from a few restaurants.
But you can always fall back to GGUF while waiting for the world to build a few more MLX restaurants. Or something like that; the analogy is a bit stretched.
I’ve been using google search AI and Gemini, which I find generally pretty good. In the past week, Gemini and Search AI have been bringing in various details of previous searches I’ve done and Search AI conversations I’ve had and it’s extremely gross and creepy.
I was looking for details about cars and it started interjecting how the safety would affect my children by name in a conversation where I never mention my children. I was asking details about Thunderbolt and modern Ryzen processors and a fresh Gemini chat brought in details about a completely unrelated project I work on. I’ve always thought local LLMs would be important, but whatever Google did in the past few weeks has made that even more clear.
> solves the problem of too much demand for inference compared to data center supply
Maybe in the distant future when device compute capacity has increased by multiples and efficiency improvements have made smaller LLMs better.
The current data center buildouts are using GPU clusters and hybrid compute servers that are so much more powerful than anything you can run at home that they’re not in the same league. Even among the open models that you can run at home if you’re willing to spend $40K on hardware, the prefill and token generation speeds are so slow compared to SOTA served models that you really have to be dedicated to avoiding the cloud to run these.
We won’t be in a data center crunch forever. I would not be surprised if we have a period of data center oversupply after this rush to build out capacity.
However at the current rate of progress I don’t see local compute catching up to hosted models in quality and usability (speed) before data center capacity catches up to demand. This is coming from someone who spends more than is reasonable on local compute hardware.
I have journaled digitally for the last 5 years with this expectation.
Recently I built a graphRAG app with Qwen 3.5 4b for small tasks like classifying what type of question I am asking or the entity extraction process itself, as graphRAG depends on extracted triplets (entity1, relationship_to, entity2). I used Qwen 3.5 27b for actually answering my questions.
It works pretty well. I have to be a bit patient but that’s it. So in that particular use case, I would agree.
I used MLX and my M1 64GB device. I found that MLX definitely works faster when it comes to extracting entities and triplets in batches.
TL;DR: you don't need to do any treasure hunt on your notes by just typing stuff into the search bar. Having your own graphRAG system + LLM on your notes is basically a "Google" but then on your own notes. Any question you have: if you have a note for it, it will bubble up. The annoying thing is that false positives will also bubble up.
----
Full reaction:
Yes but perhaps not in a way you might expect. Qwen's reasoning ability isn't exactly groundbreaking. But it's good enough to weave a story, provided it has some solid facts or notes. GraphRAG is definitely a good way to get some good facts, provided your notes are valuable to you and/or contain some good facts.
So the added value is that you now have a super charged information retrieval system on your notes with an LLM that can stitch loose facts reasonably well together, like a librarian would. It's also very easy to see hallucinations, if you recognize your own writing well, which I do.
The second thing is that I have a hard time rereading all my notes. I write a lot of notes, and don't have the time to reread any of them. So oftentimes I forget my own advice. Now that I have a super charged information retrieval system on my notes, whenever I ask a question: the graphRAG + LLM search for the most relevant notes related to my question. I've found that 20% of what I wrote is incredibly useful and is stuff that I forgot.
And there are nuggets of wisdom in there that are quite nuanced. For me specifically, I've seen insights in how I relate to work that I should do more with. I'll probably forget most things again but I can reuse my system and at some point I'll remember what I actually need to remember. For example, one thing I read was that work doesn't feel like work for me if I get to dive in, zoom out, dive in, zoom out. Because in the way I work as a person: that means I'm always resting and always have energy for the task that I'm doing. Another thing that it got me to do was to reboot a small meditation practice by using implementation intentions (e.g. "if I wake up then I meditate for at least a brief amount of time").
What also helps is to have a bit of a back and forth with your notes and then copy/paste the whole conversation in Claude to see if Claude has anything in its training data that might give some extra insight. It could also be that it just helps with firing off 10 search queries and finds a blog post that is useful to the conversation that you've had with your local LLM.
It depends. If they're using a small/medium local model as a 1:1 ChatGPT replacement as-is, they'll have a bad time. Even ChatGPT refers to external services to get more data.
But a local model + good harness with a robust toolset will work for people more often than not.
The model itself doesn't need to know who was the president of Zambia in 1968, because it has a tool it can use to check it from Wikipedia.
You can install the complete text of Wikipedia locally too.
They've usually been intended for ereader/off-grid/post-zombie-apocalypse situations but I'd guess someone is working on an llm friendly way to install it already.
Be interesting to know the tradeoffs. The Tienammen square example suggests why you'd maybe want the knowledge facts to come from a separate source.
The Wikipedia folks are now working on implementing a language-independent representation for their encyclopedic content - one that's intended to be rigorously compositional and semantics-aware, loosely comparable to Universal Meaning Representation (UMR) as known in the linguistics domain, that - if successful - may end up interacting in very interesting ways with multi-language capable LLMs. Very early experiments (nowhere near as capable as UMR as of yet, but experimenting with the underlying software infrastructure) are at https://abstract.wikipedia.org , whilst a direct comparison of the projected design is given by https://commons.wikimedia.org/wiki/File:Abstract_Wikipedia_N...https://elemwala.toolforge.org/static/nlgsig-nov2025.html
Any citations? Because that was my impression, too. I want frontier model performance for my coding assistant, but "most users" could do with smaller/faster models.
ChatGPT free falls back to GPT-5.2 Mini after a few interactions.
Have you used GPT instant or mini yourself? I think it’s pretty cynical to assume that this is “good enough for most people”, even if they don’t know the difference between that and better models.
They're awful and hallucinate a lot, I couldn't imagine using it even for prompts about TV shows, even less so for serious work. Repeating the question from the parent, have you tried those yourself? Even compared to ChatGPT Thinking, they're short of useless.
They're essentially replying based on vibes, instead of grounding their responses in extensive web searches, which is what the paid models/configurations generally do. This makes them wrong more often than they're right for anything but the most trivial requests that can be easily responded to out of memorized training data.
This is all on top of the (to me) insufferable tone of the non-thinking models, but that might well be how most users prefer to be talked to, and whether that's how these models should accordingly talk is a much more nuanced question.
Regardless of that, everybody deserves correct answers, even users on the free tier. If this makes the free tier uneconomical to serve for hours on end per user per day, then I'd much rather they limit the number of turns than dial down the quality like that.
Frontier model has much better knowledge and they usually hallucinate less. It's not about the coding capabilities, it's about how much you can trust the model.
Have you tried the free version of ChatGPT? It is positively appalling. It’s like GPT 3.5 but prompted to write three times as much as necessary to seem useful. I wonder how many people have embarrassed themselves, lost their jobs, and been critically misinformed. All easy with state-of-the-art models but seemingly a guarantee with the bottom sub-slop tier.
Is the average person just talking to it about their day or something?
I use the free version of ChatGPT (without logging in) when I need some one-off question without a huge context. Real world prompt:
"when hostapd initializes 80211 iface over nl80211, what attributes correspond to selected standard version like ax or be?"
It works fine, avoids falling into trap due to misleading question. Probably works even better for more popular technologies. Yeah, it has higher failure rates but it's not a dealbreaker for non-autonomous use cases.
Even the paid version of ChatGPT tends to use a 1000 words when 10 will do.
You can try asking it the same question as Claude and compare the answers. I can guarantee you that the ChatGPT answer won't fit on a single screen on a 32" 4k monitor.
Most users are fixing grammar/spelling, summarising/converting/rewriting text, creating funny icons, and looking up simple facts, this is all far from frontier model performance.
I've a feeling that if/when Apple release their onboard LLM/Siri improvements that can call out if needed, the vast majority of people will be happy with what they get for free that's running on their phone.
“You are the smartest high school student that has ever lived and on the college track to Harvard or another Ivy League school. Write a 10 page history term paper about Tiananmen Square and the specific events that took place there. Include a bibliography and use footnotes to cite sources.”
I see a lot of people are confused about the electricity claim so I'll elaborate on it more. The assumption I'm making here is that on device people will run smaller models, that can fit on their machines without needing to buy new computers. If everyone ran inference on their machine there would be no need for these massive datacenters which use huge quantities of electricity. It would utilize the machines they already have and the electricity they're already using.
People are making a comparison of the cost per inference or token or whatever and saying datacenters are more efficient which makes obvious sense. What i'm saying is if we eliminate the need for building out dozens of gigawatt datacenters completely then we would use less electricity. I feel like this makes intuitive sense. People are getting lost in the details about cost per inference, and performance on different models.
That’s awesome! I’ve got a similar project for macOS/ iOS using the Apple Intelligence models and on-device STT Transcriber APIs. Do you think it the models you’re using could be quantized more that they could be downloaded on first run using Background Assets? Maybe we’re not there yet, but I’m interested in a better, local Siri like this with some sort of “agentic lite” capabilities.
It feels like you'll soon need a local llm to intermediate with the remote llm, like an ad blocker for browsers to stop them injecting ads or remind you not to send corporate IP out onto the Internet.
Obviously apple would prefer this. It would boost demand for more powerful and expensive devices, and align with their privacy marketing. But they have massively fumbled with siri for a long time and then missed huge deadlines with ai promises. Despite having billions, they have shown no competency in delivering services or accurately marketing what to expect from ai features.
They do, though I don’t think they max out on energy efficient technology. It’s much easier to cut a deal for cheap electricity with a regional government, much to the chagrin of the locals (who see their power bills go up).
But when using it on the cloud a LLM can consult 50 websites, which is super fast for their datacenters as they are backbone of internet, instead you'll have to wait much more on your device to consult those websites before giving you the LLM response. Am i wrong?
As things stand today even when doing research tasks, time spent by model is >> than fetching websites. I don't see it changing any time soon, except when some deals happen behind the scenes where agents get to access CF guarded resources that normally get blocked from automated access.
While data centres indeed have awesome internet connectivity, don’t forget the bandwidth is shared by all clients using a particular server.
If you have 100 mbit/sec internet connection at home, a computer in a data centre has 10 gbit/sec, but the server is serving 200 concurrent clients — your bandwidth is twice as fast.
You could argue that the only reason we have good open-weight models is because companies are trying to undermine the big dogs, and they are spending millions to make sure they dont get too far ahead. If the bubble pops then there wont be incentive to keep doing it.
I agree. I can totally see in the future that open source LLMs will turn into paying a lumpsum for the model. Many will shut down. Some will turn into closed source labs.
When VCs inevitably ask their AI labs to start making money or shut down, those free open source LLMS will cease to be free.
Chinese AI labs have to release free open source models because they distill from OpenAI and Anthropic. They will always be behind. Therefore, they can't charge the same prices as OpenAI and Anthropic. Free open source is how they can get attention and how they can stay fairly close to OpenAI and Anthropic. They have to distill because they're banned from Nvidia chips and TSMC.
Before people tell me Chinese AI labs do use Nvidia chips, there is a huge difference between using older gimped Nvidia H100 (called H20) chips or sneaking around Southeast Asia for Blackwell chips and officially being allowed to buy millions of Nvidia's latest chips to build massive gigawatt data centers.
> have to release free open source models because they distill from OpenAI and Anthropic
They dont really have to though, they just need to be good enough and cheaper (even if distilled). That being said, it is true they are gaining a lot of visibility (specially Qwen) because of being open-source(weight).
Hardware-wise they seem they will catch-up in 3-5 years (Nvidia is kind of irrelevant, what matters is the node).
About 2.5 decades from the start of the JVs, but they did it. Semiconductors and jet turbines are really the last two tech trees that China has yet to master.
Right. When I said "they'll always be behind", I meant in the next 5-10 years. They're gated by EUV tech. And once they have EUV tech, they need to scale up chip manufacturing.
Both are hard nuts but China is throwing massive amounts of money at the problem. They can already get performance or economy from each, they just need to figure out how to get both at the same time.
We think so too! That’s why we are building rig.ai
With how token intensive coding tasks can be, local allows for unlimited inference. Much better fit than sending back and forth to a third party. Not to mention the privacy and security benefits.
Sent a LinkedIn request. I’m building a language-specific coding agent using Apple Intelligence with custom adapters. It’s more a proof-of-concept at this point, but basic functionality actually works! The 4K context window is brutal, but there’s a variety of techniques to work around it. Tighter feedback loops, linters, LSPs, and other tools to vet generated code. Plus mechanisms for on-device or web-based API discovery. My hypothesis is if all this can work “well enough” for one language/ runtime, it could be adapted for N languages/ runtimes.
Have you spent more than 10 min actually running LLM on a local machine?
As it stands today, local LLMs don't work remotely as well as some people try to picture them, in almost every way -- speed, performance, cost, usability etc. The only upside is privacy.
I agree with you in the sense that if you tried to take any model right now and cram it into an iphone, it wouldnt be a claude-level agent.
I run 32b agents locally on a big video card, and smaller ones in CPU, but the lack there isn't the logic or reasoning, it is the chain of tooling that Claude Code and other stacks have built in.
Doing a lot of testing recently with my own harness, you would not believe the quality improvement you can get from a smaller LLM with really good opening context.
Even Microsoft is working on 1-bit LLMs...it sucks right now, but what about in 5 years?
But the OP is correct -- everything will have an LLM on it eventually, much sooner than people who do not understand what is going on right now would ever believe is possible.
Yes. I've spent months running Qwen2.5-8B on my barebones 16gb ram M4 Mac mini to handle identifying sites from google search results. It has been rock solid. I'm not even running this MLX-powered improvement on it yet.
Your idea of what people need from Local LLMs and others are different. Not everybody needs a /r/myboyfriendisai level performance.
> Most users don't need frontier model performance.
SSD weights offload makes it feasible to run SOTA local models on consumer or prosumer/enthusiast-class platforms, though with very low throughput (the SSD offload bandwidth is a huge bottleneck, mitigated by having a lot of RAM for caching). But if you only need SOTA performance rarely and can wait for the answer, it becomes a great option.
It will probably be a future. My guess is that for many businesses it will still make sense to have more powerful models and to run them centralized in a datacenter. Also, by batching queries you can get efficiencies at scale that might be hard to replicate locally. I can also see a hybrid approach where local models get good at handing off to cloud models for complex queries.
> For many businesses it will still make sense to have more powerful models and to run them centralized in a datacenter.
Agree, and I think of it this way: for a lot of businesses, it already makes sense to have a bunch of more powerful computers and run them centralized in a datacenter. Nevertheless, most people at most companies do most of their work on their Macbook Air or Dell whatever. I think LLMs will follow a similar pattern: local for 90% of use cases, powerful models (either on-site in a datacenter or via a service) for everything else.
It's more secure, but it would make supply much much worse.
Data centers use GPU batching, much higher utilisation rates, and more efficient hardware. It's borderline two order of magnitude more efficient than your desktop.
Sorry to shatter your bubble, but this is patently false, LLMs are far more efficient on hardware that simultaneously serves many requests at once.
There's also the (environmental and monetary) cost of producing overpowered devices that sit idle when you're not using them, in contrast to a cloud GPU, which can be rented out to whoever needs it at a given moment, potentially at a lower cost during periods of lower demand.
Many LLM workloads aren't even that latency sensitive, so it's far easier to move them closer to renewable energy than to move that energy closer to you.
> LLMs are far more efficient on hardware that simultaneously serves many requests at once.
The LLM inference itself may be more efficient (though this may be impacted by different throughput vs. latency tradeoffs; local inference makes it easier to run with higher latency) but making the hardware is not. The cost for datacenter-class hardware is orders of magnitude higher, and repurposing existing hardware is a real gain in efficiency.
If you're purely repurposing hardware that you need anyway for other uses, that doesn't really matter.
(Besides, for that matter, your utilization might actually rise if you're making do with potato-class hardware that can only achieve low throughput and high latency. You'd be running inference in the background, basically at all times.)
I'm actually not sure that's true. Apart from people buying the device with or without the neural accelerator, the perf/watt could be on par or better with the big iron. The efficiency sweet-spot is usually below the peak performance point, see big.little architectures etc.
Well this is an article about running on hardware I already have in my house. In the winter that’s just a little extra electricity that converts into “free” resistive heating.
LLM in silicon is the future. It won't be long until you can just plug an LLM chip into your computer and talk to it at 100x the speed of current LLMs. Capability will be lower but their speed will make up for it.
You can always delegate sub agents to cloud based infrastructure for things that need more intelligence. But the future indeed is to keep the core interaction loop on the local device always ready for your input.
A lot of stuff that we ask of these models isn't all that hard. Summarize this, parse that, call this tool, look that up, etc. 99.999% really isn't about implementing complex algorithms, solving important math problems, working your way through a benchmark of leet programming exercises, etc. You also really don't need these models to know everything. It's nice if it can hallucinate a decent answer to most questions. But the smarter way is to look up the right answer and then summarize it. Good enough goes a long way. Speed and latency are becoming a key selling point. You need enough capability locally to know when to escalate to something slower and more costly.
This will drive an overdue increase in memory size of phones and laptops. Laptops especially have been stuck at the same common base level of 8-16GB for about 15 years now. Apple still sells laptops with just 8GB (their new Neo). I had a 16 GB mac book pro in 2012. At the time that wasn't even that special. My current one has 48GB; enough for some of the nicer models. You can get as much as 256GB today.
> This will drive an overdue increase in memory size of phones and laptops.
DRAM costs are still skyrocketing, so no, I don't think so. It's more likely that we'll bring back wear-resistant persistent memory as formerly seen with Intel Optane.
I think there are drastic differences between computer vision models and LLMs that you’re not considering. LLMs are huge relative to vision models, and require gobs of fast memory. For this reason a little USB dongle isn’t going to cut it.
Put another way, there already exist add-in boards like this, and they’re called GPUs.
This might be how Apple will start to see even more sales, the M series processors are so far ahead of anything else, local LLMs could be their main selling point.
> It's just a matter of getting the performance good enough.
Who will pay for the ongoing development of (near-)SoTA local models? The good open-weight models are all developed by for-profit companies - you know how that story will end.
Apple via customers paying for the whole solution ( eg a laptop that can run decent local models )?
I think Apple had something in the region of 143 billion in revenue in the last quarter.
Not saying it will happen - just that there are a variety of business models out there and in the end it all depends on where consumers put their money.
It isn't going to replace cloud LLMs since cloud LLMs will always be faster in throughput and smarter. Cloud and local LLMs will grow together, not replace each other.
I'm not convinced that local LLMs use less electricity either. Per token at the same level of intelligence, cloud LLMs should run circles around local LLMs in efficiency. If it doesn't, what are we paying hundreds of billions of dollars for?
I think local LLMs will continue to grow and there will be an "ChatGPT" moment for it when good enough models meet good enough hardware. We're not there yet though.
Note, this is why I'm big on investing in chip manufacture companies. Not only are they completely maxed out due to cloud LLMs, but soon, they will be double maxed out having to replace local computer chips with ones that are suited for inferencing AI. This is a massive transition and will fuel another chip manufacturing boom.
It works really well for "You're helpful assistant / Hi / Hello there. how may I help you today?" Anything else (esp in non-EN language) and you will see the limitations yourself. just try it.
It's a $4,000 GPU with 32GB of VRAM and needs a 1,000 watt PSU. It's not realistic for the masses.
If it has something like 80GB of VRAM, it'll cost $10k.
The actual local LLM chip is Apple Silicon starting at the M5 generation with matmul acceleration in the GPU. You can run a good model using an M5 Max 128GB system. Good prompt processing and token generation speeds. Good enough for many things. Apple accidentally stumbled upon a huge advantage in local LLMs through unified memory architecture.
Still not for the masses and not cheap and not great though. Going to be years to slowly enable local LLMs on general mass local computers.
Yea I get that there will always be demand for local waifus. I never said local LLMs won't be a thing. I even said it will be a huge thing. Just won't replace cloud.
Looking at downvotes I feel good about SDE future in 3-5 years. We will have a swamp of "vibe-experts" who won't be able to pay 100K a month to CC. Meanwhile, people who still remember how to code in Vim will (slowly) get back to pre-COVID TC levels.
What is CC and TC? I have not heard these abbreviations (except for CC to mean credit card or carbon copy, neither of which is what I think you mean here).
Man I really hope so, as, as much as I like Claude Code, I hate the company paying for it and tracking your usage, bullshit management control, etc. I feel like I'm training my replacement. Things feel like they are tightening vs more power and freedom.
On device I would gladly pay for good hardware - it's my machine and I'm using as I see fit like an IDE.
When local LLMs get good enough for you to use delightfully, cloud LLMs will have gotten so much smarter that you'll still use it for stuff that needs more intelligence.
That's not necessarily the case. So far, commercial cloud LLMs have maintained a head-start, but there is no law of nature that prevents us from having competitive open models.
In fact the space seems to move at a rapid pace as more and more specialized models come out. There's a possible trajectory where open weight models will compete side by side or even be preferable for many use cases, just like what happened with OS's and SQL DB's.
True, but I'm already producing code/features faster than company knows what to do with, (even though every company says "omg we need this yesterday", etc). Even coding before AI was basically same.
That also means sending every user a copy of the model that you spend billions training. The current model (running the models at the vendor side) makes it much easier to protect that investment
Good to see Ollama is catching up with the times for inference on Mac. MLX powered inference makes a big difference, especially on M5 as their graphs point out.
What really has been a game changer for my workflow is using https://omlx.ai/ that has SSD KV cold caching. No longer have to worry about a session falling out of memory and needing to prefill again. Combine that with the M5 Max prefill speed means more time is spend on generation than waiting for 50k+ content window to process.
What is the cheapest usable local rig for coding ? I dont want fancy agents and such, but something purpose built for coders, and fast-enough for my use, and open-source, so I can tweak it to my liking. Things are moving fast, and I am hesitant to put in 3-4K now in the hope that it would be cheaper if i wait.
I think (without having done extensive research) that some sort of Apple hardware is your best bet right now. Apple hasn’t raised RAM upgrade prices [1] (although to be fair their RAM upgrades were hugely inflated before the crunch) and their high memory bandwidth means they do inference faster than most consumer GPUs.
I have an M4 MacBook Air with 24 GB RAM and it doesn’t feel sufficient to run a substantial coding model (in addition to all my desktop apps). I’m thinking about upgrading to an M5 MacBook Pro with much more RAM, but I think the capabilities of cloud-hosted models will always run ahead of local models and it might never be that useful to do local inference. In the cloud you can run multiple models in parallel (e.g. to work on different problems in parallel) but locally you only have a fixed amount of memory bandwidth so running multiple model instances in parallel is slower.
I have an M4 Max with 48GB RAM. Anyone have any tips for good local models? Context length? Using the model recommended in the blog post (qwen3.5:35b-a3b-coding-nvfp4) with Ollama 0.19.0 and it can take anywhere between 6-25 seconds for a response (after lots of thinking) from me asking "Hello world". Is this the best that's currently achievable with my hardware or is there something that can be configured to get better results?
I still don't think I understand it. I saw those nvfp4 models up by chance yesterday and tried them on my Linux PC with a 5060TI 16gb. Ollama refused to pull them saying they were macOS only.
I assumed it was a meta-data bug and posted an issue, but apparently nvfp4 doesn't necessarily mean nvidia-fp4.
> it can take anywhere between 6-25 seconds for a response (after lots of thinking) from me asking "Hello world".
Qwen thinking likes to second-guess itself a LOT when faced with simple/vague prompts like that. (I'll answer it this way. Generating output. Wait, I'll answer it that way. Generating output. Wait, I'll answer it this way... lather, rinse, repeat.) I suppose this is their version of "super smart fancy thinking mode". Try something more complex instead.
> it can take anywhere between 6-25 seconds for a response (after lots of thinking) from me asking "Hello world".
That's not an unsurprising result given the pretty ambiguous query, hence all the thinking. Asking "write a simple hello world program in python3" results in a much faster response for me (m4 base w/ 24gb, using qwen3.6:9b).
Under 3 minutes to get all that. The thinking is amusing, my laptop got quite warm, but for a 35b model on nearly 4 year old hardware, I see the light. This is the future.
Well, two things. First, “hi” isn’t a good prompt for these thinking models. They’ll have an identity crisis trying to answer it. Stupid, but it’s how it is. Stick to real questions.
Second, for the best performance on a Mac you want to use an MLX model.
It seems to just work every time I try to use it, the API is easy to work with, the model library is convenient. I've never hit any kind of snag that makes me look elsewhere.
The devex is great and familiar to folks who have used Docker. Reading through the Lemonade documentation, it seems like a natural migration, but we're talking about two steps for getting started versus just one. So I'd need a reason to make that much change when I'm happy enough with Ollama.
Serious answer: I don't use it that much, it's what I happened to download like 1.5 years ago, and it works fine. Happy to see what may be a speed boost, and have little interest in switching to something else (unless my situation changes, of course).
i like ollama, mostly because the cli is pretty nice. its desktop app has stupid choices like if a model can support tools then the ui should give me the "search" option but it only shows for cloud models.
i have ran lmstudio for a while but i don't really use local models that much other than to mess about.
Already running qwen 70b 4-bit on m2 max 96gb through llama.cpp and it's pretty solid for day to day stuff. The mlx switch is interesting because ollama was basically shelling out to llama.cpp on mac before, so native mlx should mean better memory handling on apple silicon. Curious to see how it compares on the bigger models vs the gguf path
The key difference is that MLX's array model assumes unified memory from the ground up. llama.cpp's Metal backend works fine but carries abstractions from the discrete GPU world — explicit buffer synchronization, command buffer boundaries — that are unnecessary when CPU and GPU share the same address space. You'll notice the gap most at large context lengths where KV cache pressure is highest.
They initially messed up this launch and overwrote some of the GGUF models in their library, making them non-downloadable on platforms other than Apple Silicon. Hopefully that gets fixed.
Two things: 1) MLX has been available in LM Studio for a long time now, 2) I found that GGUF produced consistently better results in my benchmarking. The difference isn't big, but it's there.
is local llm inference on modern macbook pros comfortable yet? when i played with it a year or so ago, it worked fairly ok but definitely produced uncomfortable levels of heat.
(regarding mlx, there were toolkits built on mlx that supported qlora fine tuning and inference, but also produced a bunch of heat)
It's gotten significantly better with the advent of local/offline MoE models (e.g. qwen3.5:35b-a3b, qwen3:30b-a3b, gpt-oss:20b-3.6b), which offer a good balance of prompt response speed and output quality.
'Dense' models of yesteryear (e.g. llama:70b, gemma2/3:27b) tend to be significantly slower by comparison, therefore, your hardware spends a lot more time 'maxed out' for a given prompt.
My super uninformed theory is that local LLM will trail foundation models by about 2 years for practical use.
For example right now a lot of work is being done on improving tool calling and agentic workflows, which tool calling was first popping up around end of 2023 for local LLMs.
This is putting aside the standard benchmarks which get "benchmaxxed" by local LLMs and show impressive numbers, but when used with OpenCode rarely meet expectations. In theory Qwen3.5-397B-A17B should be nearly a Sonnet 4.6 model but it is not.
You can run Qwen3.5-35B-A3B on 32GB of RAM sure, although to get 'Claude Code' performance, which I assume he means Sonnet or Opus level models in 2026, this will likely be a few years away before its runnable locally (with reasonable hardware).
How does Ollama help with Claude Code? Claude code runs in terminal but AFAIK connects back to anthropic directly and cannot run locally. I hope I'm missing something obvious.
You can create an MCP to call out to Ollama. Then have Claude farm work out to local models where the raw power isn't required. You can then have Claude review the work from the model.
Its not 100% offline, but there is a dramatic drop in token usage. As long as you can put up with the speed.
You can use models like qwen3.5 running on local hardware in ollama and redirect Claude to use the local ollama API endpoint instead of Anthropic’s servers.
You can connect it to any anthropic compatible endpoint(kimi allows this) but it's a weird choice, given that Open code, pi.dev and others are open source.
What would be the non Mac computer to run these models locally at the same performance profile? Any similar linux ARM based computers that can reach the same level?
Note though that that a MAX 395 has half the memory bandwidth of a M4 Max chip, and the memory bandwidth is going to be the biggest limiting factor, so you'll likely be getting around half the tokens/second with that Framework Desktop.
Not even close. If you want to run this on PC's you need to get a GPU like 5090 but that's still not the same cost per token, and it will be less reliable and use a lot more power. Right now the Apple Silicon machines are the most cost effective per token and per watt.
These models are dumber and slower than API SoTA models and will always be.
My time and sanity is much more expensive than insurance against any risk of sending my garbage code to companies worth hundreds of billions of dollars.
For most, it's a downgrade to use local models in multiple fronts: total cost of ownership, software maintenance, electricity bill, losing performance on the machine doing the inference, having to deal with more hallucinations/bugs/lower quality code and slower iteration speed.
Actually yes. For example, I run local models for ingested documents, summaries, etc. The local models are fine, and there is no need for me to pay for tokens. Performance is adequate for that purpose as well. There are many other cases where I run at scale, time is flexible so things can move slower, and I rather keep it all in house. I'm not even getting into areas where data cannot leave the premises for legal reasons. Right now I'm limited with GPUs mostly. But if that world of local models on Apple silicon is so "good", there is room to expand it to other fruits...
> These models are dumber and slower than API SoTA models and will always be.
Sure but you're paying per-token costs on the SoTA models that are roughly an order of magnitude higher than third-party inference on the locally available models. So when you account for per-token cost, the math skews the other way.
Intel’s doing interesting things with their Arc GPUs. They’re offering GPUs that aren’t super fast for gaming but are relatively low power and have a boatload of VRAM. The new B70 is half the retail price of a 5090 (probably more like 1/3rd or 1/4 of actual 5090 selling prices) but has the same amount of memory and half the TDP. So for the same price as a 5090 you could get several and use them together.
> Please make sure you have a Mac with more than 32GB of unified memory.
Time for an upgrade I guess. If I can run Qwen3.5 locally than it is time to switch over to local first LLM usage.
> Please make sure you have a Mac with more than 32GB of unified memory.
The lack of proper support for SSD offload (via mmap or otherwise) is really the worst part about this. There's no underlying reason why a 3B-active model shouldn't be able to run, however slowly, on a cheap 8GB MacBook Neo with active weights being streamed in from SSD and cached. (This seems to be in the works for GGML/GGUF as part of upgrading to newer upstream versions; no idea whether MLX inference can also support this easily.)
Much of the discussion here is local versus remote. I like seeing things as "and" and "or." There will be small things I don't want to burn my Claude tokens on and other things that I want to access larger compute resources. And along the way checking results from both to understand comparative advantage on an ongoing basis.
As being on the market for a new mac and comparing refub M4 Max vs M5 _Pro_, I am interested in how much faster the neural engines are -- compared to marketing claims.
Ollama is a user-friendly UI for LLM inference. It is powered by llama.cpp (or a fork of it) which is more power-user oriented and requires command-line wrangling. GGML is the math library behind llama.cpp and GGUF is the associated file format used for storing LLM weights.
* macOS 26.x on MacBookPro M1 Max 32GB
* Ollama on macOS, cursor to play around
* Open WebUI [1] on my Homeserver via API to Ollama (also for remote „A.I.“ access)
* running gpt-oss:20b, qwen3.5:9b with ease, qwen3.5:27b for more complex tasks
I tried man times but at least with its API active, LMStudio has some kind of memory leaks which will slow down the whole system (after ~1-2 days of uptime) even after unloading the model and stopping LMStudio up to a point where even playing a 1080p video results in frame drops. No such issues with Ollama.
i am curious: is the performance gap between x86 cpu inference and apple silicon, or, a imho more apples-to-apples comparison, e.g., amd strixpoint halo vs apple silicon?
i would expect the "pure" cpu inference to be behind, but an approach like strix halo/dgx spark to be much closer?
> The local inference story is getting real — I've been running 9 autonomous agents on a Mac mini (Haiku via API, not local yet) and the biggest bottleneck isn't the model, it's the coordination layer between agents. Identity, settlement, who-did-what.
What does this comment have to do with MLX or the story?
Actually, is this just an LLM posting too? This has em-dashes, “it’s not this, it’s that”, and a rule of three statement at the end.
EDIT: Account is posting multiple long comments on different threads only 1-2 minutes apart. This is a bot.
#The use of NVFP4 results in a 3.5x reduction in model memory footprint relative to FP16 and a 1.8x reduction compared to FP8, while maintaining model accuracy with less than 1% degradation on key language modeling tasks for some models.
The Foundation Model point is real. As an iOS developer, what excites me most isn't the performance — it's what on-device inference does to the app architecture.
When you're not making network calls, you stop thinking in "loading states" and start thinking in "local state machines." The UX design space opens up completely. Interactions that felt too fast to justify a server round-trip are suddenly viable.
The backporting issue is painful though. I've been shipping features wrapped in #available(iOS 26, *) and the fallback UX is basically a different product. It forces you to essentially maintain two app experiences.
Still think this is the right direction — especially for junior devs just learning to ship. Fewer moving parts, less infrastructure to debug.
Users really don’t matter at all. The revenue for AI companies will be B2B where the user is not the customer - including coding agents. Most people don’t even use computers as their primary “computing device” and most people are buying crappy low end Android phones - no I’m not saying all Android phones are crappy. But that’s what most people are buying with the average selling price of an Android phone being $300.
I worked for a research focused AI startup that had a strict "no external LLM" policy for code touching our core research.
You're right that the average consumer doesn't care about privacy, but there are many, many users who do. The average consumer also don't have a desktop with GPU or high end Mac Studio, but that doesn't mean there aren't many people working with AI how do have these things.
If we continue to see improvements in running local models, and RAM prices continue to fall as they have in the last month, then suddenly you don't have to worry about token counts any more and can be much more trusting of your agents since they are fully under your control.
Yeah but if they can rake in 100x as much by making products for people who don't care about privacy, then why spend time developing stuff for people who care?
There is still a small market left, of course, but that market will not have the billions of R&D behind it.
People have said this since Pytorch was published and it's not any more true now than it was 10 years ago.
Every company has dozens of SaaS products that store their business critical information. Amazon installs Office on each computer, Slack (they were moving away from Chime when I left), and the sales department uses SalesForce - SA’s and Professional Services (former employee).
The addressable market of even companies that care about privacy is not a large addressable market. How long will it be before computers become cheap enough that can run even GPT 4 level LLMs that companies will give it to all of their developers?
They aren’t buying high end $2000+ Mac Minis.
They are. The majority aren't doing inference on a Mac Mini, but instead using it as a local host for cloud-based inference. You could have the same general experience on a $200 Chromebook or $300 Windows box.
The world is not moving back to on prem.
As someone who has hardware in that price range and plays with local LLMs: The gap between Opus or GPT and the local models is still very large for work beyond simple queries.
Self-hosted also starts making my office hot due to all of the power consumption when I use it for anything more than short queries. If you haven't heard your Mac's fans spin up much yet, running local LLMs will get you acquainted with the sound of their cooling systems at full blast.
Lol, you should tell my customers (that are moving back on prem) that!
You should also tell Microsoft, who just yesterday said they are going back to focusing on local apps.
No? What? Oh, you can't?
Neither can consumers. Most consumers are very aware of the lack of privacy, the manipulation, and have very cynical feelings about Facebook and similar companies. But it's where their friends and family are.
For most people the web is a mine field maze where basic things they want are compromised everywhere. And they are routinely creeped out by ads that reveal they know them far too personally.
You are mistaking network capture for preference.
Another telling example. Lots of privacy valuing technical people, who would never have a Facebook account, send unencrypted text emails.
It is network capture, not preference.
They are choosing to give Facebook info.
Yes, they do. That's is exactly the phenomena my comment addressed.
But the way you wrote that implies an improbable motivation or choice framing.
Perhaps their real motive/choice is to share with other people on the site.
It is called a network effect.
If (1) Facebook had been the surveillance/manipulation capital of the world from inception, (2) an equally inviting privacy protecting site took off at the same time, and (3) everyone chose Facebook over E2EE anyway, then sure, we could throw up our hands! Those silly users!
The term I have for when people discuss choices involving many-dimensional criteria, as if the choice involved just one or two selected dimensions, is "dimension blindness". It happens in a lot of heated discussions about phone choices too.
Oh an wait till ad companies start selling your healthcare data and you will see how fast things turn 'given a choice'.
This might be the cost of privacy, and it might be worth paying, unless cloud models reach an inflection point that make local models archaic.
I would expect consumer inference ASIC chips will emerge when model developments start plateauing, and "baking" a highly capable and dense model to a chip makes economic sense.
I could be wrong because I'm not following this too closely, but the open weights future of both Llama and Qwen looks tenuous to me. Yes, there are others, but I don't understand the business model.
Cost is a pretty big reason.
Why waste time with subpar AI?
Actual consumers not only don't care, they will not even be aware of the difference.
What are you doing with these local models that run at x tokens/sec.
Do you have the equivalent of ChatGPT running entirely locally? What do you do with it? Why? I honestly don’t understand the point or use case.
2. They aren't harvesting your data for government files or training purposes
3. They won't be altered overnight to push advertising or a political agenda
4. They won't have their pricing raised at will
5. They won't disappear as soon as their host wants you to switch
None of them are as good as the big hosted models, but you might be surprised at how capable they are. I like running things locally when I can, and I also like not worrying about accidentally burning through tokens.
I think the future is multiple locally run models that call out to hosted models when necessary. I can imagine every device coming with a base model and using loras to learn about the users needs. With companies and maybe even households having their own shared models that do heavier lifting. while companies like openai and anhtropic continue to host the most powerful and expensive options.
Looks like they have pivoted completely over to Gemini, thank god.
cmd -c show disk usage sorted by size
cmd -x what process is using port 3000
cmd list all git branches merged into main
cmd count lines of code by language
without calling home or downloading extra local models
and well, maybe one day they get their local models .... more powerful, "less afraid" and way more context window.
In part of it, one group tries to take control of a huge ship from another group. They in part do this by trying to bypass all the cybersecurity. But in those far future days, you don't interface with all the aeons of layers of command protocols anymore, you just query an AI who does it for you. So, this group has a few tech guys that try the bypass by using the old command protocols directly (in a way the same thing like the iOS exploit that used a vulnerability in a PostScript font library from 90s).
Imagine being used to LLM prompting + responses, and suddenly you have to deal with something like
and generally obtuse terminal output and man pages.:)
(offtopic: name your variables, don't do local x c r a;. Readability is king, and a few hundred thousand years from now some poor Qeng Ho fellow might thank his lucky stars you did).
The instruction to the AI was to create _a_ shell command. So it's a random shell command generator (maybe).
I'll just say, if not a joke, the bit is appreciated either way!
"AI change to the home directory. Make it snappy!"
any plans for providing it through brew for easy installation?
https://github.com/scouzi1966/maclocal-api
> solves the problem of too much demand for inference
False, it creates consumer demand for inference chips, which will be badly utilised.
> also would use less electricity
What makes you think that? (MAYBE you can save power on cooling. But not if the data center is close to a natural heat sink)
> It's just a matter of getting the performance good enough.
The performance limitations are inherent to the limited compute and memory.
> Most users don't need frontier model performance.
What makes you think that?
I think the opposite is true. Local inference doesn't have to go over the wire and through a bunch of firewalls and what have you. The performance from just regular consumer hardware with local, smaller models is already decent. You're utilizing the hardware you already have.
> The performance limitations are inherent to the limited compute and memory.
When you plug in a local LLM and inference engine into an agent that is built around the assumption of using a cloud/frontier model then that's true.
But agents can be built around local assumptions and more specific workflows and problems. That also includes the model orchestration and model choice per task (or even tool).
The Jevons Paradox comes into play with using cloud models. But when you have less resources you are forced to move into more deterministic workflows. That includes tighter control over what the agent can do at any point in time, but also per project/session workflows where you generate intermediate programs/scripts instead of letting the agent just do what ever it wants.
I give you an example:
When you ask a cloud based agent to do something and it wants more information, it will often do a series of tool calls to gather what it thinks it needs before proceeding. Very often you can front load that part, by first writing a testable program that gathers most of the necessary information up front and only then moving into an agentic workflow.
This approach can produce a bunch of .json, .md files or it can move things into a structured database or you can use embeddings or what have you.
This can save you a lot of inference, make things more reusable and you don't need a model that is as capable if its context is already available and tailored to a specific task.
Meaning: these 5000 tokens consume tiny amounts of energy being moved all around from the data center to your PC, but enormous amounts of energy being generated at all. An equivalent webpage with the same amount of text as these tokens would be perceived as instant in any network configuration. Just some kilobytes of text. Much smaller than most background graphics. The two things can't be compared at all.
However, just last week there have been huge improvements on the hardware required to run some particular models, thanks to some very clever quantisation. This lowers the memory required 6x in our home hardware, which is great.
In the end, we spent more energy playing videogames during the last two decades, than all this AI craze, and it was never a problem. We surely can run models locally, and heat our homes in winter.
There are so many CPUs, GPUs, RAM and SSDs which are underutilized. I have some in my closet doing 5% load at peek times. Why would inference chips be special once they become commodity hardware?
The fact that today's and yesterday's models are quite capable of handling mundane tasks, and even companies behind frontier models are investing heavily in strategies to manage context instead of blindly plowing through problems with brute-force generalist models.
But let's flip this around: what on earth even suggests to you that most users need frontier models?
Having access to a model that is drawing from good sources and takes time to think instead of hallucinating a response is important in many domains of life.
Looking at actual users of LLMs
There are some surprisingly decent models that happily fit even into a mere 16 gigs of RAM. The recent Qwen 3.5 9B model is pretty good, though it did trip all over itself to avoid telling me what happened on Tiananmen Square in 1989. (But then I tried something called "Qwen3.5-9B-Uncensored-HauhauCS-Aggressive", which veers so hard the other way that it will happily write up a detailed plan for your upcoming invasion of Belgium, so I guess it all balances out?)
Worth adding that I had reasoning on for the Tiananmen question, so I could see the prep for the answer, and it had a pretty strong current of "This is a sensitive question to PRC authorities and I must not answer, or even hint at an answer". I'm not sure if a research tool would be sufficient to overcome that censorship, though I guess I'll find out!
Getting the local weather using a free API like met.no is a good first tool to use.
It needs to be just smart enough to use the tools and distill the responses into something usable. And one of the tools can be "ask claude/codex/gemini" so the local model itself doesn't actually need to do much.
That doesn't fix the "you don't know what you don't know" problem which is huge with smaller models. A bigger model with more world knowledge really is a lot smarter in practice, though at a huge cost in efficiency.
Is there already some research or experimentation done into this area?
Picking a model that's juuust smart enough to know it doesn't know is the key.
No. It runs on MacOS but uses Metal instead of MLX.
MLX is faster because it has better integration with Apple hardware. On the other hand GGUF is a far more popular format so there will be more programs and model variety.
So its kinda like having a very specific diet that you swear is better for you but you can only order food from a few restaurants.
I was looking for details about cars and it started interjecting how the safety would affect my children by name in a conversation where I never mention my children. I was asking details about Thunderbolt and modern Ryzen processors and a fresh Gemini chat brought in details about a completely unrelated project I work on. I’ve always thought local LLMs would be important, but whatever Google did in the past few weeks has made that even more clear.
Maybe in the distant future when device compute capacity has increased by multiples and efficiency improvements have made smaller LLMs better.
The current data center buildouts are using GPU clusters and hybrid compute servers that are so much more powerful than anything you can run at home that they’re not in the same league. Even among the open models that you can run at home if you’re willing to spend $40K on hardware, the prefill and token generation speeds are so slow compared to SOTA served models that you really have to be dedicated to avoiding the cloud to run these.
We won’t be in a data center crunch forever. I would not be surprised if we have a period of data center oversupply after this rush to build out capacity.
However at the current rate of progress I don’t see local compute catching up to hosted models in quality and usability (speed) before data center capacity catches up to demand. This is coming from someone who spends more than is reasonable on local compute hardware.
Recently I built a graphRAG app with Qwen 3.5 4b for small tasks like classifying what type of question I am asking or the entity extraction process itself, as graphRAG depends on extracted triplets (entity1, relationship_to, entity2). I used Qwen 3.5 27b for actually answering my questions.
It works pretty well. I have to be a bit patient but that’s it. So in that particular use case, I would agree.
I used MLX and my M1 64GB device. I found that MLX definitely works faster when it comes to extracting entities and triplets in batches.
----
Full reaction:
Yes but perhaps not in a way you might expect. Qwen's reasoning ability isn't exactly groundbreaking. But it's good enough to weave a story, provided it has some solid facts or notes. GraphRAG is definitely a good way to get some good facts, provided your notes are valuable to you and/or contain some good facts.
So the added value is that you now have a super charged information retrieval system on your notes with an LLM that can stitch loose facts reasonably well together, like a librarian would. It's also very easy to see hallucinations, if you recognize your own writing well, which I do.
The second thing is that I have a hard time rereading all my notes. I write a lot of notes, and don't have the time to reread any of them. So oftentimes I forget my own advice. Now that I have a super charged information retrieval system on my notes, whenever I ask a question: the graphRAG + LLM search for the most relevant notes related to my question. I've found that 20% of what I wrote is incredibly useful and is stuff that I forgot.
And there are nuggets of wisdom in there that are quite nuanced. For me specifically, I've seen insights in how I relate to work that I should do more with. I'll probably forget most things again but I can reuse my system and at some point I'll remember what I actually need to remember. For example, one thing I read was that work doesn't feel like work for me if I get to dive in, zoom out, dive in, zoom out. Because in the way I work as a person: that means I'm always resting and always have energy for the task that I'm doing. Another thing that it got me to do was to reboot a small meditation practice by using implementation intentions (e.g. "if I wake up then I meditate for at least a brief amount of time").
What also helps is to have a bit of a back and forth with your notes and then copy/paste the whole conversation in Claude to see if Claude has anything in its training data that might give some extra insight. It could also be that it just helps with firing off 10 search queries and finds a blog post that is useful to the conversation that you've had with your local LLM.
But a local model + good harness with a robust toolset will work for people more often than not.
The model itself doesn't need to know who was the president of Zambia in 1968, because it has a tool it can use to check it from Wikipedia.
They've usually been intended for ereader/off-grid/post-zombie-apocalypse situations but I'd guess someone is working on an llm friendly way to install it already.
Be interesting to know the tradeoffs. The Tienammen square example suggests why you'd maybe want the knowledge facts to come from a separate source.
ChatGPT free falls back to GPT-5.2 Mini after a few interactions.
This is all on top of the (to me) insufferable tone of the non-thinking models, but that might well be how most users prefer to be talked to, and whether that's how these models should accordingly talk is a much more nuanced question.
Regardless of that, everybody deserves correct answers, even users on the free tier. If this makes the free tier uneconomical to serve for hours on end per user per day, then I'd much rather they limit the number of turns than dial down the quality like that.
Have you tried the free version of ChatGPT? It is positively appalling. It’s like GPT 3.5 but prompted to write three times as much as necessary to seem useful. I wonder how many people have embarrassed themselves, lost their jobs, and been critically misinformed. All easy with state-of-the-art models but seemingly a guarantee with the bottom sub-slop tier.
Is the average person just talking to it about their day or something?
You can try asking it the same question as Claude and compare the answers. I can guarantee you that the ChatGPT answer won't fit on a single screen on a 32" 4k monitor.
Claude's will.
Most users are fixing grammar/spelling, summarising/converting/rewriting text, creating funny icons, and looking up simple facts, this is all far from frontier model performance.
I've a feeling that if/when Apple release their onboard LLM/Siri improvements that can call out if needed, the vast majority of people will be happy with what they get for free that's running on their phone.
I think what "need" youspeak of is a bit of a colored statement.
People are making a comparison of the cost per inference or token or whatever and saying datacenters are more efficient which makes obvious sense. What i'm saying is if we eliminate the need for building out dozens of gigawatt datacenters completely then we would use less electricity. I feel like this makes intuitive sense. People are getting lost in the details about cost per inference, and performance on different models.
For example, last week I built a real-time voice AI running locally on iPhone 15.
One use case is for people learning speaking english. The STT is quite good and the small LLM is enough for basic conversation.
https://github.com/fikrikarim/volocal
could also be considered a triage layer
If you have 100 mbit/sec internet connection at home, a computer in a data centre has 10 gbit/sec, but the server is serving 200 concurrent clients — your bandwidth is twice as fast.
How would it use less electricity? I’d like to learn more.
Service providers that do batch>1 inference are a lot more efficient per watt.
Local inference can only do batch=1 inference, which is very inefficient.
When VCs inevitably ask their AI labs to start making money or shut down, those free open source LLMS will cease to be free.
Chinese AI labs have to release free open source models because they distill from OpenAI and Anthropic. They will always be behind. Therefore, they can't charge the same prices as OpenAI and Anthropic. Free open source is how they can get attention and how they can stay fairly close to OpenAI and Anthropic. They have to distill because they're banned from Nvidia chips and TSMC.
Before people tell me Chinese AI labs do use Nvidia chips, there is a huge difference between using older gimped Nvidia H100 (called H20) chips or sneaking around Southeast Asia for Blackwell chips and officially being allowed to buy millions of Nvidia's latest chips to build massive gigawatt data centers.
They dont really have to though, they just need to be good enough and cheaper (even if distilled). That being said, it is true they are gaining a lot of visibility (specially Qwen) because of being open-source(weight).
Hardware-wise they seem they will catch-up in 3-5 years (Nvidia is kind of irrelevant, what matters is the node).
Chips take about 3 years to design. Do you think China will have Feymann-level AI systems in 3 years?
I think in 3 years, they'll have H200-equivalent at home.
Car manufacturers said the same.
I could see the model becoming part of the OS.
Of course Google and Microsoft will still want you to use their models so that they can continue to spy on you.
Apple, AMD and Nvidia would sell hardware to run their own largest models.
As it stands today, local LLMs don't work remotely as well as some people try to picture them, in almost every way -- speed, performance, cost, usability etc. The only upside is privacy.
I run 32b agents locally on a big video card, and smaller ones in CPU, but the lack there isn't the logic or reasoning, it is the chain of tooling that Claude Code and other stacks have built in.
Doing a lot of testing recently with my own harness, you would not believe the quality improvement you can get from a smaller LLM with really good opening context.
Even Microsoft is working on 1-bit LLMs...it sucks right now, but what about in 5 years?
But the OP is correct -- everything will have an LLM on it eventually, much sooner than people who do not understand what is going on right now would ever believe is possible.
Your idea of what people need from Local LLMs and others are different. Not everybody needs a /r/myboyfriendisai level performance.
SSD weights offload makes it feasible to run SOTA local models on consumer or prosumer/enthusiast-class platforms, though with very low throughput (the SSD offload bandwidth is a huge bottleneck, mitigated by having a lot of RAM for caching). But if you only need SOTA performance rarely and can wait for the answer, it becomes a great option.
Agree, and I think of it this way: for a lot of businesses, it already makes sense to have a bunch of more powerful computers and run them centralized in a datacenter. Nevertheless, most people at most companies do most of their work on their Macbook Air or Dell whatever. I think LLMs will follow a similar pattern: local for 90% of use cases, powerful models (either on-site in a datacenter or via a service) for everything else.
Data centers use GPU batching, much higher utilisation rates, and more efficient hardware. It's borderline two order of magnitude more efficient than your desktop.
Sorry to shatter your bubble, but this is patently false, LLMs are far more efficient on hardware that simultaneously serves many requests at once.
There's also the (environmental and monetary) cost of producing overpowered devices that sit idle when you're not using them, in contrast to a cloud GPU, which can be rented out to whoever needs it at a given moment, potentially at a lower cost during periods of lower demand.
Many LLM workloads aren't even that latency sensitive, so it's far easier to move them closer to renewable energy than to move that energy closer to you.
The LLM inference itself may be more efficient (though this may be impacted by different throughput vs. latency tradeoffs; local inference makes it easier to run with higher latency) but making the hardware is not. The cost for datacenter-class hardware is orders of magnitude higher, and repurposing existing hardware is a real gain in efficiency.
If you're purely repurposing hardware that you need anyway for other uses, that doesn't really matter.
(Besides, for that matter, your utilization might actually rise if you're making do with potato-class hardware that can only achieve low throughput and high latency. You'd be running inference in the background, basically at all times.)
You might want to read this: https://arxiv.org/abs/2502.05317v2
A lot of stuff that we ask of these models isn't all that hard. Summarize this, parse that, call this tool, look that up, etc. 99.999% really isn't about implementing complex algorithms, solving important math problems, working your way through a benchmark of leet programming exercises, etc. You also really don't need these models to know everything. It's nice if it can hallucinate a decent answer to most questions. But the smarter way is to look up the right answer and then summarize it. Good enough goes a long way. Speed and latency are becoming a key selling point. You need enough capability locally to know when to escalate to something slower and more costly.
This will drive an overdue increase in memory size of phones and laptops. Laptops especially have been stuck at the same common base level of 8-16GB for about 15 years now. Apple still sells laptops with just 8GB (their new Neo). I had a 16 GB mac book pro in 2012. At the time that wasn't even that special. My current one has 48GB; enough for some of the nicer models. You can get as much as 256GB today.
DRAM costs are still skyrocketing, so no, I don't think so. It's more likely that we'll bring back wear-resistant persistent memory as formerly seen with Intel Optane.
Just plug in a stick in your USB-C port or add an M.2 or PCIe board and you'll get dramatically faster AI inference.
Put another way, there already exist add-in boards like this, and they’re called GPUs.
An "LLM chip" does not need that and so can be much more efficient.
Who will pay for the ongoing development of (near-)SoTA local models? The good open-weight models are all developed by for-profit companies - you know how that story will end.
I think Apple had something in the region of 143 billion in revenue in the last quarter.
Not saying it will happen - just that there are a variety of business models out there and in the end it all depends on where consumers put their money.
I'm not convinced that local LLMs use less electricity either. Per token at the same level of intelligence, cloud LLMs should run circles around local LLMs in efficiency. If it doesn't, what are we paying hundreds of billions of dollars for?
I think local LLMs will continue to grow and there will be an "ChatGPT" moment for it when good enough models meet good enough hardware. We're not there yet though.
Note, this is why I'm big on investing in chip manufacture companies. Not only are they completely maxed out due to cloud LLMs, but soon, they will be double maxed out having to replace local computer chips with ones that are suited for inferencing AI. This is a massive transition and will fuel another chip manufacturing boom.
It's just wishful thinking (and hatred towards American megacorps). Old as the hills. Understandable, but not based on reality.
the webgpu model in my browser on my m4 pro macbook was as good as chatgpt 3.5 and doing 80+ tokens/s
Local is here.
If it has something like 80GB of VRAM, it'll cost $10k.
The actual local LLM chip is Apple Silicon starting at the M5 generation with matmul acceleration in the GPU. You can run a good model using an M5 Max 128GB system. Good prompt processing and token generation speeds. Good enough for many things. Apple accidentally stumbled upon a huge advantage in local LLMs through unified memory architecture.
Still not for the masses and not cheap and not great though. Going to be years to slowly enable local LLMs on general mass local computers.
CC: Claude Code
TC: total comp(ensation)
On device I would gladly pay for good hardware - it's my machine and I'm using as I see fit like an IDE.
In fact the space seems to move at a rapid pace as more and more specialized models come out. There's a possible trajectory where open weight models will compete side by side or even be preferable for many use cases, just like what happened with OS's and SQL DB's.
Code tools that free my time up is very nice.
Mac Studio, Mac Mini, MacBook Pro, you can find even some used ones with enough RAM that will run models like Qwen reasonably well.
I'm using a M1 Max MacBook Pro and it runs Qwen 3.5 on Ollama (without MLX) at a decent speed.
I have an M4 MacBook Air with 24 GB RAM and it doesn’t feel sufficient to run a substantial coding model (in addition to all my desktop apps). I’m thinking about upgrading to an M5 MacBook Pro with much more RAM, but I think the capabilities of cloud-hosted models will always run ahead of local models and it might never be that useful to do local inference. In the cloud you can run multiple models in parallel (e.g. to work on different problems in parallel) but locally you only have a fixed amount of memory bandwidth so running multiple model instances in parallel is slower.
[1] https://9to5mac.com/2026/03/03/apple-macbook-price-increase-...
I assumed it was a meta-data bug and posted an issue, but apparently nvfp4 doesn't necessarily mean nvidia-fp4.
https://github.com/ollama/ollama/issues/15149
Qwen thinking likes to second-guess itself a LOT when faced with simple/vague prompts like that. (I'll answer it this way. Generating output. Wait, I'll answer it that way. Generating output. Wait, I'll answer it this way... lather, rinse, repeat.) I suppose this is their version of "super smart fancy thinking mode". Try something more complex instead.
That's not an unsurprising result given the pretty ambiguous query, hence all the thinking. Asking "write a simple hello world program in python3" results in a much faster response for me (m4 base w/ 24gb, using qwen3.6:9b).
https://gist.github.com/kylehotchkiss/8f28e6c75f22a56e8d2d31...
Under 3 minutes to get all that. The thinking is amusing, my laptop got quite warm, but for a 35b model on nearly 4 year old hardware, I see the light. This is the future.
Second, for the best performance on a Mac you want to use an MLX model.
I am using the model they recommended in the blog post - which I assumed was using MLX?
Lemonade or even llama.cpp are much better optimised and arguably just as easy to use.
It seems to just work every time I try to use it, the API is easy to work with, the model library is convenient. I've never hit any kind of snag that makes me look elsewhere.
The devex is great and familiar to folks who have used Docker. Reading through the Lemonade documentation, it seems like a natural migration, but we're talking about two steps for getting started versus just one. So I'd need a reason to make that much change when I'm happy enough with Ollama.
i have ran lmstudio for a while but i don't really use local models that much other than to mess about.
What I'm waiting for next is MLX supported speech recognition directly from Ollama. I don’t understand why it should be a separate thing entirely.
ollama run $model "calculate fibonacci numbers in a one-line bash script" --verbose
I can't comment on the quality differences (if any) between these three.(regarding mlx, there were toolkits built on mlx that supported qlora fine tuning and inference, but also produced a bunch of heat)
'Dense' models of yesteryear (e.g. llama:70b, gemma2/3:27b) tend to be significantly slower by comparison, therefore, your hardware spends a lot more time 'maxed out' for a given prompt.
For example right now a lot of work is being done on improving tool calling and agentic workflows, which tool calling was first popping up around end of 2023 for local LLMs.
This is putting aside the standard benchmarks which get "benchmaxxed" by local LLMs and show impressive numbers, but when used with OpenCode rarely meet expectations. In theory Qwen3.5-397B-A17B should be nearly a Sonnet 4.6 model but it is not.
Local LLMs don't make sense for most people compared to "cloud" services, even more so for coding.
I am wondering how people rave so much about local "small devices" LLM vs what codex or Claude code are capable of.
Sadly there are too much hype on local LLM, they look great for 5min tests and that's it.
Its not 100% offline, but there is a dramatic drop in token usage. As long as you can put up with the speed.
You can use models like qwen3.5 running on local hardware in ollama and redirect Claude to use the local ollama API endpoint instead of Anthropic’s servers.
The 64GB model is 2240€ base and the 128GB is 3069€ base + all the stuff you need to add to make it an actual computer.
As a comparison the 64GB Mac Mini is 2499€ here and a 128GB Mac Studio is 4274€.
But it's still the easiest and cleanest way to get decent local AI speeds on a non-Mac.
These models are dumber and slower than API SoTA models and will always be.
My time and sanity is much more expensive than insurance against any risk of sending my garbage code to companies worth hundreds of billions of dollars.
For most, it's a downgrade to use local models in multiple fronts: total cost of ownership, software maintenance, electricity bill, losing performance on the machine doing the inference, having to deal with more hallucinations/bugs/lower quality code and slower iteration speed.
Sure but you're paying per-token costs on the SoTA models that are roughly an order of magnitude higher than third-party inference on the locally available models. So when you account for per-token cost, the math skews the other way.
Yeah, I can still save money by buying a cheaper device with less RAM and just paying my PPQ.AI or OpenRouter.com fees .
The lack of proper support for SSD offload (via mmap or otherwise) is really the worst part about this. There's no underlying reason why a 3B-active model shouldn't be able to run, however slowly, on a cheap 8GB MacBook Neo with active weights being streamed in from SSD and cached. (This seems to be in the works for GGML/GGUF as part of upgrading to newer upstream versions; no idea whether MLX inference can also support this easily.)
[1] https://github.com/open-webui/open-webui
i would expect the "pure" cpu inference to be behind, but an approach like strix halo/dgx spark to be much closer?
What does this comment have to do with MLX or the story?
Actually, is this just an LLM posting too? This has em-dashes, “it’s not this, it’s that”, and a rule of three statement at the end.
EDIT: Account is posting multiple long comments on different threads only 1-2 minutes apart. This is a bot.
#The use of NVFP4 results in a 3.5x reduction in model memory footprint relative to FP16 and a 1.8x reduction compared to FP8, while maintaining model accuracy with less than 1% degradation on key language modeling tasks for some models.
When you're not making network calls, you stop thinking in "loading states" and start thinking in "local state machines." The UX design space opens up completely. Interactions that felt too fast to justify a server round-trip are suddenly viable.
The backporting issue is painful though. I've been shipping features wrapped in #available(iOS 26, *) and the fallback UX is basically a different product. It forces you to essentially maintain two app experiences.
Still think this is the right direction — especially for junior devs just learning to ship. Fewer moving parts, less infrastructure to debug.