Counterpoint: when readers and authors inhabit the same intellectual circle and have read the same foundational works, most alpha is in the details.

Try training an LLM from random initialization, with zero tokens of grammatical language anywhere in its training data or prompt. It’s not gonna spontaneously emit grammatical language!

Empirically, training a group of LLMs from random initialization in a shared environment with zero tokens of grammatical language in their training data does seem to get them to spontaneously emit tokens with interpretable meaning. From Emergence of Grounded Compositional Language in Multi-Agent Populations (Mordatch & Abbeel, 2017):

In this paper, we propose a physically-situated multiagent learning environment and learning methods that bring about emergence of a basic compositional language. This language is represented as streams of abstract discrete symbols uttered by agents over time, but nonetheless has a coherent structure that possesses a defined vocabulary and syntax. The agents utter communication symbols alongside performing actions in the physical environment to cooperatively accomplish goals defined by a joint reward function shared between all agents. There are no pre-designed meanings associated with the uttered symbols - the agents form concepts relevant to the task and environment and assign arbitrary symbols to communicate them.
[...]
In this work, we consider a physically-simulated two-dimensional environment in continuous space and discrete time. This environment consists of N agents and M landmarks. Both agent and landmark entities inhabit a physical location in space p and posses descriptive physical characteristics, such as color and shape type. In addition, agents can direct their gaze to a location v.Agents can act to move in the environment and direct their gaze, but may also be affected by physical interactions with other agents. We denote the physical state of an entity (including descriptive characteristics) by x and describe its precise details and transition dynamics in the Appendix. In addition to performing physical actions, agents utter verbal communication symbols c at every timestep. These utterances are discrete elements of an abstract symbol vocabulary C of size K.

We do not assign any significance or meaning to these symbols. They are treated as abstract categorical variables that are emitted by each agent and observed by all other agents. It is up to agents at training time to assign meaning to these symbols. As shown in Section , these symbols become assigned to interpretable concepts. Agents may also choose not to utter anything at a given timestep, and there is a cost to making an utterance, loosely representing the metabolic effort of vocalization. We denote a vector representing one-hot encoding of symbol c with boldface c.
[...]
We observe a compositional syntactic structure emerging in the stream of symbol uttered by agents. When trained on environments with only two agents, but multiple landmarks and actions, we observe symbols forming for each of the landmark colors and each of the action types. A typical conversation and physical agent configuration is shown in first row of Figure 4 and is as follows: Green Agent: GOTO, GREEN, ... Blue Agent: GOTO, BLUE, ... The labels for abstract symbols are chosen by us purely for interpretability and visualization and carry no meaning for training. While there is recent work on interpreting continuous machine languages (Andreas, Dragan, and Klein 2017), the discrete nature and small size of our symbol vocabulary makes it possible to manually labels to the symbols. See results in supplementary video for consistency of the vocabulary usage.

Do you expect that scaling up that experiment would not result in the emergence of a shared grammatical language? Is this a load-bearing part of your expectation of why transformer-based LLMs will hit a scaling wall?

If so, that seems like an important crux that is also quite straightforward to test, at least relative to most of the cruxes people have on here which have a tendency towards unfalsifiability.

This still suffers from the incentive gradient pushing quite hard to just build end-to-end agents. Not only will it probably work better, but it'll be straight up cheaper and easier!

The same is true of human software developers - your dev team sure can ship more features at a faster cadence if you give them root on your prod servers and full read and write access to your database. However, despite this incentive gradient, most software shops don't look like this. Maybe the same forces that push current organizations to separate out the person writing the code from the person reviewing it could be repurposed to software agents.

One bottleneck, of course, is that one reason it works with humans is that we have skin in the game - sufficiently bad behavior could get us fired or even sued. Current AI agents don't currently have anything to gain from behaving well or lose from behaving badly (or sufficient coherence to talk about "an" AI agent doing a thing).

Yeah, openai/guided-diffusion is basically that. Here's an example colab which uses CLIP guidance to sample openai/guided-diffusion (not mine, but I did just verify that the notebook still runs)

The short answer is "mode collapse" (same author as Simulators and also of generative.ink, where that LLM-generated HPMOR continuation I linked came from).

My best crack at the medium answer in 15 minutes or less is:

The base model is tuned to predict the next token of text drawn from its training distribution, which means that sampling from the base model will produce text which resembles its training corpus by any statistical measure the model has learned (with 405b that is effectively "any statistical test you can think of", barring specifically chosen adversarial ones).

My mental model of base models (one that I think is pretty well supported empirically) is that they are giant bags of contextually activated heuristics. Some such heuristics are very strong and narrow ("if the previous tokens were "Once upon a", we are at 4th word of fairy tail, when 4th word of fairy tale, output " time"), and some are wide and weak ("French words tend to be followed by other French words"). And these heuristics are almost exclusively where the model gets its capabilities (there are a few weird exceptions like arithmetic and date munging).

Instruct- or chat-tuned models have secondary objectives that are not simply "predict the next token". My mental model is that RL is extremely lazy, and will tend to chisel in the simplest possible behavior into the model which causes decreased loss / increased reward. One extremely simple behavior is "output a memorized sequence of text". This behavior is also very discoverable and easy to reinforce - most of the update just needs to be "get the model to output the first couple tokens of the memorized sequence". There's a variant "fill in the mad lib" that is also quite easy to discover.

And so unless you make specific efforts to prevent it, doing RL on an LLM will give you a model which consistently falls into a few attractors. This is really hard to prevent - even if your base model and your RL'd model have almost identical logprobs for almost all low-perplexity prefixes you can still fall into these attractors (once you're in one of these attractors you're no longer looking at text which the base model is trained to predict super accurately).

The very long answer I would like to give at some point involves seeing how few token substitutions in base model output it takes to convert those outputs into something that looks almost identical to a given chat-tuned model - in other words, have a base and a chat model provide completions for a given prompt, and then replace the base model output token with the chat model output token at the single highest KL divergence position and resample the base model, and repeat.

Can there be a generative AI whose output has non-averageness on all levels, in the same proportions as human-generated content?

Isn't this called a "base model"?

If you say to your favorite chat-tuned LLM "write me a poem about a hamster driving a jeep", it'll say something like "Sure, here's a poem about a hamster driving a jeep: <the most generic imaginable poem about a hamster driving a jeep>". If you prompt a base model like llama-3.1-405b base with "Write me a poem about a hamster driving a jeep" you'll get back whatever text was most likely to follow that sentence.

That could be something like the next question on a hallucinated exam

It might be a free-verse "poem" which appears to be the ravings of a madman

It might even write some low quality actual rhyming poetry

It is possible to write fiction this way, using lots of rollouts at every point and then sampling the best one. There's even dedicated software for doing this. But the workflow isn't as simple as "ask your favorite LLM chatbot".

Ah, yep. Thanks!

You have to dig for it on nysenate.gov but you can also find it there: the most recent version of this is A6453B not A6453A. Not sure why the "download bill full text" links to the first version of a bill rather than the most up-to-date one.

6. “Frontier model” means either of the following: (a) an artificial intelligence model trained using greater than 10^26 computational operations (e.g., integer or floating-point operations), the compute cost of which exceeds one hundred million dollars; OR (b) an artificial intelligence model produced by applying knowledge distillation to a frontier model as defined in paragraph (a) of this subdivision, provided that the compute cost for such model produced by applying knowledge distillation exceeds five million dollars.

Where did you go to see the version of the bill with the bolded part? Looking at the bill here, which is the only link to the text of the bill I see on nysenate.gov, I see the definition as

"Frontier model" means either of the following: (a) an artificial intelligence model trained using greater than 10º26 computational operations (e.g., integer or floating-point operations), the compute cost of which exceeds one hundred million dollars; or (b) an artificial intelligence model produced by applying knowledge  distillation to a frontier model as defined in paragraph (a) of this subdivision.

The "where the distillation costs at least $5M" seems very important to have the bill not affect e.g. a hedge fund that has trained $100M of specialized models, at least one of which cost $5M, and then separately has had an intern spend a couple hundred dollars distilling the llama 4 behemoth model (if that one happens to be over the 10^26 mark, which it is if it's as overtrained as the rest of the llama series)

FWIW I did not see any high-valur points made on Twitter that were not also made on HN.

Oh, one more source for that one though - there was some coverage on the Complex Systems podcast - the section titled "AI's impact on reverse engineering" (transcript available at that URL).

There was a good discussion on hacker news, and there was quite a bit of posting of highly variable quality on xitter.