AI Alignment Forum

The paper that killed deep learning theory

I like this post and the "theory of deep learning" posts. But I think I still haven't figured out how to model your view, especially the specifics of the pessimism here. Maybe we should discuss in person. In particular I'm not sure what "deep learning theory" encompasses. My sense of mechinterp theory is that it's similar to pre- standard model physics. Heuristically, here's a thought experiment. Suppose we're worried about the sun destroying the earth and want to understand as much as possible about the physics of solar plasmas and supernovas; but we currently only have (a vaguely historical pastiche of) pre-WW2 physics. Physics then roughly had the following components: 1. idealized heuristics: if we view a big object in space as a classical blackbody, we get a good heuristic on some parts of its emission spectrum 2. new behaviors: there's a consistent way that emission spectra aren't classical blackbodies, in that they're quantized. We have only a rough understanding of how and why, and in fact this observation spawned the discovery of quantum mechanics. 3. small toy examples: we can understand the hydrogen atom relatively well. There are some weird factors of 2 and corrections that we can only explain kind of heuristically, but except for these we have a clean, exact quantized spectrum. We see this spectrum in real life materials - but we also see that most of what comprises real materials isn't hydrogen, and is much more complicated. Some stuff still looks roughly like they could be atomic spectra for other atoms or small molecules, but metal conducting bands are dominated by weird and clearly non-localized behaviors that we don't understand (and the sun similarly has weird spectral phenomena). 4. limits. There's a limit where the world is Newtonian, which is sometimes useful, but very inaccurate when modeling the sun. There's a limit where the world is relativistic. This gives directionally good corrections for some stellar phenomena (e.g. redshift) but is not nearly enough. It seems that there are maybe other limits (like we can mostly blackbox nuclear phenomena at earth temperatures but not at solar temperatures). Most of our understanding comes from sloppily combining together different phenomena coming from the various limits of importance. 5. experimental tools: looking at emission spectra is a really low-bandwidth way to interact with behaviors of interest. While it gives interesting info that points to new phenomena, it at best tells us something about a very limited class of behaviors (photon absorption and emission). In order to understand "how QM works" we have to figure out new tools (maybe vacuum chambers and primitive colliders), and new ways to interpret the output of existing tools. In our world, iterating on these techniques gave us the standard model (and we understood solar plasma and some basics of supernovas before this). I think the promise of theory is that analogs of these techniques (maybe: SAE, large-N limits, toys like mod-add) will give us robust mechanism-finding tools. I think a lot of criticism of theory sounds to me like someone who in that world is saying "none of the current tools explain the sun even approximately, so we're on the wrong track" - but that's not how theory works (until you've found a "critical mass" of the standard model, or at least all parts of it relevant in a field of interest, you'll only be explaining tiny fractions of the observations). I know you're not making this criticism, but I feel like currently you are flattening the different components above into one notion of "theory good vs. theory bad". I'd guess that you're skeptical about whether the analogs of 1-5 in ML theory are actually useful for "making progress towards the standard model", but I'm not sure from your post which of these you think is most lacking (or if this picture is even compatible with your criticism). My guess is that your issue is wrt something like my #1: certain heuristics that people were excited about and hoped would explain generalization turned out to be more complicated. My view is that in modern theory, VC dimension is considered largely defunct in models with nontrivially interesting data (even as simple as mod-add), but I'm not sure why this is the important thing about theory. If you take a more modern theory like mean field or even NTK, it has a non-VC notion of generalization: e.g. NTK/ Gaussian processes can replicate generalization in mnist (related to some data spectrum properties), and mean field theory can (currently only on the Bayesian level - this is unpublished work with Kaarel) explain generalization on polynomially many samples of any mechanism that can be encoded in a small (algorithms) circuit. It's of course not guaranteed to converge to the same mechanism, but has the same notion of learnable vs. un-learnable on a polynomial-vs-exponential complexity theory level. It also does replicate the correct modular addition generalizing algorithm (NTK does not).

Sam Marks13d*507

Current AIs seem pretty misaligned to me

This is one of my favorite LessWrong posts ever (strong upvoted). Nevertheless, in this comment I'll provide some pushback; not to any the particular claims made, but around a sort of "missing mood" that I think a stronger version of this post could have addressed. (For context, I'm probably one of the lab employees who sometimes says things like "Current AIs are pretty aligned"—i.e. one of the people that Ryan is arguing against here, though I might not be a very central example.) For me, the value of this post was the following: 1. Articulating a specific way that current AIs are "misaligned." Namely: 2. 1. They follow heuristics that are well-tuned for strong task performance in easy-to-verify settings, but only try superficially at difficult-to-evaluate tasks. 2. They communicate in ways that misrepresent how much they've accomplished: punching up their successes while omitting or downplaying failures, and sometimes outright lying about what they did. But they don't seem to do this strategically or persistently, instead following simple heuristics that result in these sorts of misrepresentations. 3. The overall result is that they underperform their potential at difficult-to-evaluate tasks while misleading users about what they've actually accomplished. 4. I say "misaligned" in quotes, because many traditional notions of misalignment wouldn't have covered the above, especially 1(a). This will be relevant later. 3. Providing concrete examples and a sense of how prevalent the above issues are. I want to be clear that (2) was an update for me. I think the way that you (Ryan) use LLMs more reliably elicits the sort of misalignment you name, relative to most use cases I've personally seen. (Namely, it seems like you try to use LLMs to autonomously complete very difficult tasks using scaffolds that rely extensively on self-critique.) So after reading your post, I now think that current AIs are more misaligned (in the sense you describe) than I previously thought. That said, this update was more quantitative in nature than qualitative. I was certainly aware that current AIs sometimes display the behaviors you describe, even if I thought they were somewhat rarer than I now believe. And I don't think that I personally underrated the importance of these behaviors. (Though it's possible that others did.) [ETA: After thinking about this more, I think I probably was underestimating the importance of these behaviors before reading an early draft of Ryan's post.] Given that, what could I possibly mean when I call current AIs "pretty aligned"? I think there's a hypothetical dual post to yours someone could write titled "Current AIs seem pretty aligned to me." This post would name a bunch of types of misalignment that, a few years ago, seemed could plausibly occur in AIs as capable as current ones. For instance, it seems to me that: 1. Current AIs do not training-game, i.e. actively model the training process and take actions that result in high reward (including in training environments very different from ones they've previously encountered). 2. Current AIs do persistently and coherently pursue malign goals across many contexts, e.g. strategically seeking power. 3. Current AIs do not scheme, i.e. strategically subvert their training process, pre-deployment audits, and other types of oversight. 4. Current AIs do not strategically take steps to cover up their mistakes, and will generally admit to them when asked directly. 5. Current AIs generally don't try to strategically influence things in the real world beyond assisting with (or refusing) the task directly presented to them. E.g. they don't sneakily try to funnel money to causes or people they like by influencing unrelated conversations. Instead, I think the most important way that current AIs are misaligned is the way you describe in your post, Notably, I think the type of misalignment described in your post is "less scary" than the types I list above. The misalignment happens on the "learned heuristics" level, rather than on the "active"/"strategic"/"explicit" level. As a result, it's easier to detect and measure, and less likely to cause harms besides "making the AIs less useful than they could be for certain types of tasks." A related point is that the way that current AIs are misaligned is less "adversarial" than the sorts of misalignment I list above. When I speak to the people who IMO are extremely thoughtful about AI safety, they acknowledge something like "Yeah, TBH a few years ago, I thought that AIs as capable as current ones would be misaligned in some of those ways. There's a real positive update here." But people who are merely "quite" thoughtful sometimes instead: * argue that maybe current AIs are misaligned in some of these ways and we just can't tell * * I'm very skeptical of this! Anyone who thinks this should be trying really hard to produce compelling evidence in current models. * munge definitions to try to count the "misaligned heuristics" types of misalignment as one of these more "coherent" types * claim that they never expected AIs as capable as current ones to be misaligned in these ways * * I'm typically skeptical of this, though I believe it for some people. (A related point that I know how to state more vividly: Sometimes, people like to point at clear alignment issues in frontier models—for instance, sycophancy, AI psychosis, or whatever happened with Sydney/Bing chat—as being negative updates about alignment. But they don't like to count absence of these sorts of alignment issues as being positive updates. In other words, if it hypothetically ended up that AI psychosis were somehow a total media hoax, would the the people who updated negatively on it instead say "Nevermind! Actually, the absence of AI psychosis is a positive update on alignment." Are they currently saying this about the ways that current AIs are not misaligned but could have been?) Overall, my point is that I think current AIs are not misaligned in many of the ways that I—and I think many others—expected them to be. I also think that many people I talk to have not grappled with this observation sufficiently and updated their world models and prioritization accordingly. For instance, I think that the AI safety community is overinvested in scheming research relative to scalable oversight research. (TBC I've believed this for some years now, but I now believe it more confidently and think it's more clear that others should agree with me.) I also think that the AI safety community is underinvested in work on directly automating alignment research. (This is a place where I've changed my mind.) I'll close by emphasizing some things that I do not believe and don't mean to claim in this comment: 1. I don't think that the recent overall evidence has clearly been positive about misalignment risk. For instance, timelines are looking quite short now, which IMO is the main negative update to counteract the positive one I discuss in this comment. 2. I don't think these "scarier" types of misalignment are very unlikely to eventually arise in more capable AIs. Though I do think that we should update that they'll first arise in more capable AIs than we previously thought. This makes it more likely that we'll have human-level or superhuman automated alignment researchers prior to these "scarier" types of misalignment. 3. I don't think that the type of misalignment you name in your post is "not a big deal." In particular, I'm quite worried that "we"(=AI developers or humanity as a whole) bungle the situation because we failed to make AIs capable at difficult-to-evaluate tasks like alignment research or advising us about how to handle things during a rapid intelligence explosion. One possible way we could bungle the situation is to train more capable AIs that are misaligned in some of the "scarier" ways I listed (or in other ways I didn't list). 4. I don't think that current AIs are aligned enough to automate alignment research. (An earlier draft of your post operationalized "pretty misaligned" in this way, which I preferred.)

TsviBT15d1532

You can only build safe ASI if ASI is globally banned

Recent Discussion

Crisp Supra-Decision Processes

Brittany Gelb

7mo

Introduction

In this post, we describe a generalization of Markov decision processes (MDPs) and partially observable Markov decision processes (POMDPs) called crisp supra-MDPs and supra-POMDPs. The new feature of these decision processes is that the stochastic transition dynamics are multivalued, i.e. specified by credal sets. We describe how supra-MDPs give rise to crisp causal laws, the hypotheses of infra-Bayesian reinforcement learning. Furthermore, we discuss how supra-MDPs can approximate MDPs by a coarsening of the state space. This coarsening allows an agent to be agnostic about the detailed dynamics while still having performance guarantees for the full MDP.

Analogously to the classical theory, we describe an algorithm to compute a Markov optimal policy for supra-MDPs with finite time horizons. We also prove the existence of a stationary optimal policy for...

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0XelaP1d

I'm a bit confused about how the loss is incurred. For example, in the classical case, suppose we have a lever that gives a 50/50 chance of +1/-1 loss. Then our loss doesn't just depend on the action. It seems like you'd have to do the same trick here, where you encode the lever's result as the state, and then have pulling the lever stochastically transition you between states. For both that case and the supra-bandit case, it seems like the loss that you incur on a transition should really be the loss that you got from the previous lever's result. That is, say you pull the lever and got the good outcome. Then, you pull again and transition to the bad outcome, but get the loss according to the good outcome from the previous turn. Then, when you pull the lever again, you'll get the loss of the bad outcome, etc. This does seem to make your time discounting 'one step' slow, which you'd either want to correct or just leave as it is.

Vanessa Kosoy3h20

Shifting the losses by one time step doesn't really matter, since we're mostly interested in the shape of the regret bound which (up to mild changes in the constants) is not affected by this.

The other paper that killed deep learning theory

LawrenceC

Yesterday, I wrote about the state of deep learning theory circa 2016,^[1] as well as the bombshell 2016 paper by Zhang et al. that arguably signaled its demise. Today, I cover the aftermath, and the 2019 paper that devastated deep learning theory again.

As a brief summary, I argued that the rise of deep learning posed an existential challenge to the dominant theoretical paradigm of statistical learning theory, because neural networks have a lot of complexity. The response from the field was to attempt to quantify other ways in which the hypothesis class of neural networks in practice was simple, using alternative metrics of complexity. Zhang et al. 2016 showed that the standard neural network architectures trained with standard training methods could memorize large quantities of random labelled data,...

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2LawrenceC2d

Yeah, good question. I think the word "data-dependent" has different connotations (even if it is standard terminology). Using the sketch definition [...] You're right that properties of h are, in general different from properties of the data. The "data-dependent" part enters this inequality when the right hand side depends on properties of the learned hypothesis , which depend on the training data you sampled . In classical bounds, the RHS depends only on properties of the class H (VC dim, Rademacher complexity of the whole class), not on any particular h. Those give the same number for every S. Meanwhile, the spectral-norm bounds described in that section of the post will depend on the weights of the learned network (and are, as a rule, higher on memorizing solutions than generalizing ones). (Of course, a sufficiently nitpicky person might argue that the data-dependent bounds are uniform-convergence bounds over an implicit, S-indexed sub-class — "all h' with ‖W'‖_spec ≤ ‖W(S)‖_spec". But given this sub-class is S-indexed, I think it's still fair to call the bound data-dependent.) I think this is a reasonable confusion, and I'll expand the footnote to clarify.

2DanielFilan19h

So is that h not part of the universal quantification over h in H?

2DanielFilan14h

Oh I currently think the thing that's going on is that it's a hypothesis-dependent bound that you then apply to the hypothesis learned from the data.

LawrenceC13h20

Yep

An Introduction to Credal Sets and Infra-Bayes Learnability

Brittany Gelb

8mo

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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2XelaP1d

a subset? Why is it not just that product space? I'm assuming it's because this is a set of partial functions, but I don't see how taking a subset lets you account for that. The way I would think to allow partial functions is to just say that two total function policies define the same 'actual' policy when they agree on the set of histories consistent with the policy. [...] In this case, as written, you don't need to say "An open set is then an arbitrary union of basis elements" - every open set looks like \Prod_{i \in (A \times O)^*} U_i with U_i \subseteq A and U_i = A for cofinitely many i. In general, if your U_i range over the open subsets of A, then you don't need to take unions to get the topology - you already have all of the open sets in your basis. If instead U_i range over a basis for A, then you do need to take unions. Since here A is given the discrete topology, you can just range over subsets of A, which you have done.

Vanessa Kosoy1d20

a subset? Why is it not just that product space? I'm assuming it's because this is a set of partial functions, but I don't see how taking a subset lets you account for that.

You're absolutely right, it should be a quotient space, not a subspace. In principle, it can be represented as a closed subspace of the product of copies of , where stands for "undefined".

In this case, as written, you don't need to say "An open set is then an arbitrary union of basis elements"

Actually, we do? For example, consider the space . Then the following set is open:

However, thi... (read more)

An Introduction to Reinforcement Learning for Understanding Infra-Bayesianism

Brittany Gelb

Introduction

The goal of this post is to give a summary of classical reinforcement learning theory that primes the reader to learn about infra-Bayesianism, which is a new framework for reinforcement learning that aims to solve problems related to AI alignment. We will concentrate on basic aspects of the classical theory that have analogous concepts in infra-Bayesianism, and explain these concepts using infra-Bayesianism conventions. The more technical proofs are contained in the proof section.

For the first part of this sequence and for links to other writings, see What is Inadequate about Bayesianism for AI Alignment: Motivating Infra-Bayesianism.

One special case of reinforcement learning is the case of stochastic bandits. For example, a bird may have a choice of three levers. When the bird steps on a lever, either some...

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2XelaP1d

Earlier, the momentary loss L was defined more generally, as a function of type (A \times O)^* -> [0,1]. Here, it appears as if L is only a function of the current observation, as opposed to being able to take the entire history into account. Alternatively I may have misunderstood. The alternative interpretation that comes to mind is that the total loss is only allowed to be constructed by time discounting a loss function of observations only.

Vanessa Kosoy1d20

You're right, it's supposed to be

where is the prefix of of length . The formula in the post is written for the special case where the momentary loss only depends on the last observation, but it should been stated in full generality.

2XelaP2d

Huh? The total-variation metric is induced by (1/2 of) the 1-norm, not the 2-norm. They induce the same topology, sure, but it's not the euclidean norm.

2Vanessa Kosoy2d

Good catch, this sentence is very confused.

Risk from fitness-seeking AIs: mechanisms and mitigations

Alex Mallen

Current AIs routinely take unintended actions to score well on tasks: hardcoding test cases, training on the test set, downplaying issues, etc. This misalignment is still somewhat incoherent, but it increasingly resembles what I call "fitness-seeking"—a family of misaligned motivations centered on performing well in training and evaluations (e.g., reward-seeking). Fitness-seeking warrants substantial concern.

In this piece, I lay out what I take to be the central mechanisms by which fitness-seeking motivations might lead to human disempowerment, and propose mitigations to them. While the analysis is inherently speculative, this kind of speculation seems worthwhile: AI control emerged from explicitly taking scheming motivations seriously and asking what interventions are implied, and my hope is that developing mitigations for fitness-seeking will benefit from similar forward-looking analysis.

Fitness-seekers are, in many ways, notably safer than what I'll...

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Richard Ngo's Shortform

Richard_Ngo

Linda Linsefors2d30

I think you're making the distinction more confusing than it has to be.

There are things that has motivational pull, and there are things that don't but I do them anyway because they are a necessary step to get what I actually want.

Say I want to get an apple, and the easiest way to get one is going to the store and by some. Going to the sore in this story is clearly an instrumental goal, and enjoying eating my apple is a terminal goal^[1]

Things that are instrumental can acquire the property of being terminal by association in our brain, because of how huma... (read more)

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Introduction

Introduction

Defining Credal Sets

Introduction