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Why we should expect ruthless sociopath ASI

LLM in practice these days do include increasingly bigger % of RL wich seems like it should at least make you less certain about capabilities mostly coming from pretraining and papers from before that continuing to be relevant for very long and you do mention it on the other post but still wrote that capabilities come mostly from pretraining on the footnote?. I expect an optimist or someone from the comparatively-less-pessimistic group would argue that LLM or LLM +RL might lead to consequentialists that have human-like goals due to being built from a base of human imitation even as they move towards ASI. And an important disagrement with those people there is that you don't in fact expect LLM +RL to work. You also don't think LLM+ RL would be safe if they did work but still feels relevant because It comes from pretty diferent models of how LLM will improve. Relatedly a question you are not answering here is why you think imitation learning won't lead to discovering things that are far from the distribution of humans since its unclear what the limits are out of distribution and this also seems like you have a strong view on human imitation not generalicing much to the point It won't be even be able to do human level inventing of new things wich seems like would imply bad imitation of humans, as humans can do things like invent writting. You seem to be describing a shallow kind of imitation wich seems like a nontrivial asumtion people in the LLM camp would likely disagree with?. "rocket arbitrarily far past human training data" is mixing the question of "will LLM think in ways that are very diferent from humans" with something like " can LLM only shalowly reuse reasoning from their training data and not invent new things". Perfect human imitators will just rocket arbitrarily far past human training data in the first sense and invent writting etc.

Gordon Seidoh Worley11d33

Distinguish between inference scaling and "larger tasks use more compute"

I think there's a hidden variable in this framework: the effective branching factor of the task. For well-specified tasks (prove this theorem, implement this API to spec, etc.), AI cost probably does scale roughly linearly with task size, matching your model. But most real-world engineering tasks aren't like that. The bottleneck isn't execution speed, it's the iterative discovery of what the task actually is. A senior engineer doing a 4-hour task isn't typing for 4 hours. They're making dozens of micro-decisions informed by tacit knowledge about the codebase, the product, the users, the org. They're constantly pruning the search space. An AI working autonomously on the same task produces tokens faster but explores a much larger space of wrong approaches, because it lacks that contextual judgment. So the cost might scale superlinearly with task complexity not because of compute limits but because of specification limits. This suggests the linear regime on your Pareto frontier might be shorter for real-world task distributions than for benchmark-style tasks, and the "fraction of human cost" metric could look very different depending on how well-specified the task is. The tasks where AI efficiency looks great (tight feedback loops, clear success criteria) are not the same tasks that fill most of an engineer's day. (Though note that obviously this could change if AI starts to have more context and better judgement, which would basically mean training a better model.)

Daniel Kokotajlo14d83

It Is Reasonable To Research How To Use Model Internals In Training

> training process is “the most forbidden technique”, including recent criticism of Goodfire for investing in this area. I think this mischaracterizes the criticism. The criticism as I understand it is that Goodfire is planning to help frontier AI companies use model internals in training, in exchange for money. Insofar as they really are planning to do this, then I'll count myself as among the critics, for the classic "but we need interpretability tools to be our held-out test set for alignment" reason. Do you have a link to the criticism you are responding to?

14ryan_greenblatt

IMO, this post makes several locally correct points, but overall fails to defeat the argument that misaligned AIs are somewhat likely to spend (at least) a tiny fraction of resources (e.g., between 1/million and 1/trillion) to satisfy the preferences of currently existing humans. AFAICT, this is the main argument it was trying to argue against, though it shifts to arguing about half of the universe (an obviously vastly bigger share) halfway through the piece.[1] When it returns to arguing about the actual main question (a tiny fraction of resources) at the end here and eventually gets to the main trade-related argument (acausal or causal) in the very last response in this section, it almost seems to admit that this tiny amount of resources is plausible, but fails to update all the way. I think the discussion here and here seems highly relevant and fleshes out this argument to a substantially greater extent than I did in this comment. However, note that being willing to spend a tiny fraction of resources on humans still might result in AIs killing a huge number of humans due to conflict between it and humans or the AI needing to race through the singularity as quickly as possible due to competition with other misaligned AIs. (Again, discussed in the links above.) I think fully misaligned paperclippers/squiggle maximizer AIs which spend only a tiny fraction of resources on humans (as seems likely conditional on that type of AI) are reasonably likely to cause outcomes which look obviously extremely bad from the perspective of most people (e.g., more than hundreds of millions dead due to conflict and then most people quickly rounded up and given the option to either be frozen or killed). I wish that Soares and Eliezer would stop making these incorrect arguments against tiny fractions of resources being spent on the preference of current humans. It isn't their actual crux, and it isn't the crux of anyone else either. (However rhetorically nice it might be.) -------

Recent Discussion

Why we should expect ruthless sociopath ASI

Steven Byrnes

The conversation begins

(Fictional) Optimist: So you expect future artificial superintelligence (ASI) “by default”, i.e. in the absence of yet-to-be-invented techniques, to be a ruthless sociopath, happy to lie, cheat, and steal, whenever doing so is selfishly beneficial, and with callous indifference to whether anyone (including its own programmers and users) lives or dies?

Me: Yup! (Alas.)

Optimist: …Despite all the evidence right in front of our eyes from humans and LLMs.

Me: Yup!

Optimist: OK, well, I’m here to tell you: that is a very specific and strange thing to expect, especially in the absence of any concrete evidence whatsoever. There’s no reason to expect it. If you think that ruthless sociopathy is the “true core nature of intelligence” or whatever, then you should really look at yourself in a mirror and...

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2Steven Byrnes1d

Right, I think LLMs are good at imitating “Joe today”, and good at imitating “Joe + 1 month of learning Introductory Category Theory”, but not good at imitating the delta between those, i.e. the way that Joe grows and changes over that 1 month of learning—or at least, not “good at imitating” in a way that would generalize to imitating a person learning a completely different topic that’s not in the training data. In other words, after watching 1000 people try to learn category theory over the course of a month (while keeping diaries), I claim that an LLM would learn category theory itself, and it would learn all the common misconceptions about category theory that people make as they start learning, but it wouldn’t learn “the general process of learning and sense-making itself” in a way that allows it to then autonomously invent some field that has not been invented yet. I had a long comment-thread argument with Cole Wyeth on this general topic last year: link. We didn’t resolve our disagreement and I eventually bowed out of the conversation, but you might find it helpful anyway. See especially my analogy to trying to imitation-learn AlphaZero improving itself through self-play. My answer is “obviously not”. Here’s an example: Imagine that the “competent adult humans” were all from 100 years before linear algebra existed, and we are hoping that they will invent linear algebra. Now, linear algebra involves a giant pile of interlinked concepts: matrices, bases, rank, nullity, spans, determinants, trace, eigenvectors, dual space, unitarity, and on and on. Now take a parade of these “competent human adults” with no prior exposure to any of this, and give them an hour each before they get fired, but they are allowed to send notes to each other. The goal is for them to collectively invent the entire edifice of linear algebra from scratch. I think it’s doomed. If you take a person who has never seen linear algebra before, then it will just take them a lot of time (much

2RohanS4h

I'd be curious for you to say a bit more in response to this point from above: I'm moderately optimistic about our ability to get roughly human-like consequentialism from LLM-based AGI, with character training instilling a non-ruthless non-sociopath character that is still compatible with lots of consequentialist agency, like very good scientists/inventors/entrepreneurs/etc. who never do anything that could be very dangerous (because a bunch of useful things aren't that risky, and because they have good enough moral principles to deliberately avoid or be careful around things that are risky). I think long-horizon RL or reflection or other components of the continual learning process could break the instilled character, but it seems >50% likely to me that between the preliminary character training and ongoing training and prompting to maintain good character, those things won't dominate, and we'll just have nice AIs. (I get a bit more nervous about this argument for ASI, but I think it may well hold up even there.)

Steven Byrnes3h20

The thing I’m skeptical of is maintaining non-ruthless behavior in the presence of arbitrary amounts of open-ended continual learning. By “open-ended continual learning”, I mean something analogous to what humans did between 30000 BC and today, e.g. inventing new fields, and then still more new fields that build on those new fields, etc. And the AI has to do that without any human input, given enough time.

My actual belief is that this kind of open-ended continual learning is simply impossible in LLMs. If I’m wrong about that, then I would next claim that i... (read more)

2Steven Byrnes2d

That’s this part: A workable solution (to building stable non-ruthlessness within a powerful consequentialist framework like RL + model-based planning) probably exists, and I’m obviously working on it myself, and I think I’m making gradual progress, but I think the appropriate overall attitude right now is pessimism and panic about where we’re at. See “oh man, are we dropping this ball” section here & the three-part disjunction here. (Why only “probably exists”? Because the human example is highly suggestive but not an airtight proof. For example, for all I know right now, maybe making a nice human requires a “training environment” that entails growing up with a human body, in a human community, at human speed. Doing that with AI is not really feasible in practice, for many reasons. There are other things like that too. Presumably further research will eventually either find a plan for non-ruthlessness + powerful capabilities in ASI, or a good argument that no plan exists, and I don’t currently have a very strong opinion on which one it would be.)

Formalizing Newcombian Problems with Fuzzy Infra-Bayesianism

Brittany Gelb

3mo

Introduction

In this post, we introduce contributions and supracontributions^[1], which are basic objects from infra-Bayesianism that go beyond the crisp case (the case of credal sets). We then define supra-POMDPs, a generalization of partially observable Markov decision processes (POMDPs). This generalization has state transition dynamics that are described by supracontributions.

We use supra-POMDPs to formalize various Newcombian problems in the context of learning theory where an agent repeatedly encounters the problem. The one-shot version of these problems are well-known to highlight flaws with classical decision theories.^[2] In particular, we discuss the opaque, transparent, and epsilon-noisy versions of Newcomb's problem, XOR blackmail, and counterfactual mugging.

We conclude by stating a theorem that describes when optimality for the supra-POMDP relates to optimality for the Newcombian problem. This theorem is significant because it gives...

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1Cole Wyeth2d

Contributions are in a natural one-to-one correspondence with weighted probability measures, which were studied by Joe Halpern: https://arxiv.org/pdf/1302.5681 Simply take the weight to be the sum of measure. Halpern and Leung advocated minimizing regret against a set of weighted probability measures, which seems to be the same as minimizing loss against a supracontribution? They update weights by likelihood ratio, roughly speaking (I am not sure how this corresponds to IB, since updating is not discussed in this sequence). @Vanessa Kosoy @Diffractor Do you know if there is a meaningful connection between Halpern's work and IBDT? Unrelatedly: I like the term semi-environment (the AIXI literature uses "chronological semimeasure" with apparently the same meaning, which is much worse - previously even "chronological contextual semimeasure"!). I'd like to start using your term, but maybe it would lead to some confusion as applied to my current research - I've been treating semimeasures as (lower probabilities for) credal sets in with a worst-case decision rule, while your contributions are actually best-case interpretations of (semi)measure loss!

Vanessa Kosoy15h20

Halpern and Leung propose the "minimax weighted expected regret" (MWER) decision-rule, which is a generalization of the minimax-expected-regret (MER) decision-rule. In contrast, our decision rule is a weighted generalization of maximin-expected-utility (MMEU). The problem with MER is that it doesn't work very well with learning. The closest thing to doing learning with MER is adversarial bandits. However, adversarial regret is statistically intractable for Markov Decision Processes. And even with bandits there is a hidden obliviousness assumption if you try to interpret it in a principled decision-theoretic way.

Individual AI representatives don't solve Gradual Disempowerement

Jan_Kulveit

9mo

Imagine each of us has an AI representative, aligned to us, personally. Is gradual disempowerment solved?^[1] In my view, no; at the same time having AI representatives helps at the margin.

I have two deep reasons for skepticism.^[2] Here is the first one.

Humans are Not Alone

We, as individuals, are not the only agents or “agencies” in this world. Other goal-oriented strategic entities include states, corporations, and to some extent egregores.

For the sake of argument, imagine the current distribution of agency in the world as approximately 60% humans, 20% corporations, 20% states (numbers are illustrative, egregores not included for simplicity)

Now, suppose we introduce individually aligned AI assistants for each person. At first glance, this seems empowering—each individual gains a cognitive extension, potentially leveling the playing field.

But: do corporations or states also...

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Tom Davidson20h10

What's the story for why companies end up doing things that are catastrophic for their shareholders? (Feel free to give state the key points briefly, Im familiar with many of the ideas)

An issue with training schemers with supervised fine-tuning

Fabien Roger

This is a rough write-up of ideas by Ryan Greenblatt. The core ideas are his and mistakes are mine. Thanks to him, Buck Shlegeris and to Aghyad Deeb for feedback on the draft of this post.

One way to use scheming AIs is to train them to imitate humans. When does imitation robustly avoid frequent and intentional failures?

On single-token classification tasks, imitation works great and can allow you to get a lot of high-quality labor with a tiny rate of intentional failures;
On tasks that involve generating many tokens, imitation potentially fails by default: schemers could notice when an output was generated by themselves, which enables them to consistently behave badly in deployment while doing best-effort imitation during training.

We describe two techniques that avoid imitation failures on generation tasks:

...

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1Lukas Finnveden1d

Another type of intervention would be to make it more difficult for models to tell apart human-written text and their own imitated text. E.g. maybe we could get another model M to rewrite both humans' and models' text in ways that preserve semantics but change syntactics around a bit randomly. We could train with a GAN-like scheme to make it hard for models to tell apart M([human-written text]) and M([model-written text]). (Along with some other objective that incentivizes preserving semantics.) * This would mean that, if there's any quirks of human writing that models can recognize but struggle to generate, M could learn to remove those quirks. * Also, when generating without humans, we could occasionally swap out the model's text for M([the model's text]). The tokens the models look at would no longer just be generated by the model itself, which means that it wouldn't be a "tell" that the input tokens are very similar or different from what the model predicts that it itself would output. (Which should get very predictable in late layers of the model.)

Lukas Finnveden1d10

An Introduction to Credal Sets and Infra-Bayes Learnability

Brittany Gelb

6mo

Introduction

Credal sets, a special case of infradistributions^[1] in infra-Bayesianism and classical objects in imprecise probability theory, provide a means of describing uncertainty without assigning exact probabilities to events as in Bayesianism. This is significant because as argued in the introduction to this sequence, Bayesianism is inadequate as a framework for AI alignment research. We will focus on credal sets rather than general infradistributions for simplicity of the exposition.

Defining Credal Sets

Recall that the total-variation metric is one example of a metric on $Δ X,$ the set of probability distributions over a finite set $X .$ A set is closed with respect to a metric if it contains all of its limit points with respect to the metric. For example, let $X_{0} = {0, 1} .$ The set of probability distributions over $X_{0}$ is given by

Δ X_{0} = {P : P (0) = a, P (1) = 1 - a, a \in [0, 1]} .

There is a bijection between $Δ X_{0}$ and the closed interval $[0, 1],$ which is...

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2Cole Wyeth2d

@Aram Ebtekar and I were discussing the definition of IB regret. It seems quite complicated, with three levels of mixture (!): prob mixture of Knightian uncertainty over prob mixtures. I understand the motivation for the inner two levels, but why now take a probabilistic mixture over crisp causal laws? It seems rather strange to weight laws in such as way that the choice of law is (epistemically?) stochastic, but then regret against the law itself is worst-case... I do not have a precise objection to this, I'm just curious if there is some justification / intuition for why this is a reasonable definition?

2Vanessa Kosoy2d

First, Bayes-regret and worst-case-regret are standard concepts in classical RL theory, and the infra-versions are straightforward analogs. Second, you don't have to focus on the Bayes-regret necessarily. In fact, in our papers, we focus entirely on uniform (worst-case) regret bounds. Third, instead of an ordinary prior over laws you can consider an infraprior over laws (i.e. have ambiguity in hypothesis-space and not just in outcome-space). The resulting notion of "infra-Bayes-regret" has both Bayes-regret and worst-case-regret as special cases. Fourth, the justification is quite straightforward. If you have an (unambiguous i.e. ordinary probability distribution) prior over laws, and your performance metric is the Bayes-infra-expected utility, then the Bayes-regret is just the difference between the performance of your policy and the performance of an optimal policy that magically knows the true hypothesis. So it's a very natural measure of your policy's ability to learn the hypothesis.

1Cole Wyeth1d

That makes sense (particularly proving worst-case results). Since a law, in general, means that the truth is outside of your hypothesis space and you can’t assign a probability distribution, in what sort of situation can you nevertheless justify a probability distribution over laws (rather than Knightian uncertainty)?

Vanessa Kosoy1d60

The truth is outside of my hypothesis class, but my hypothesis class probably contains a non-trivial law that is a coarsening of the truth, which is the whole point.

For example, you can imagine that you start with some kind of intractable simplicity prior. Then, for each hypothesis you choose a tractable law that coarsens it. You end up with a probability distribution over laws.

A different way to view this is, this is just a way to force your policy to have low-regret w.r.t. all/most hypothesis while weighing complex hypotheses less. For a complex hypothe... (read more)

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Introduction

Humans are Not Alone

Introduction

Defining Credal Sets