2025-12-04 02:37:04

Published on December 3, 2025 6:37 PM GMT

Tl;dr

AI alignment has a culture clash. On one side, the “technical-alignment-is-hard” / “rational agents” school-of-thought argues that we should expect future powerful AIs to be power-seeking ruthless consequentialists. On the other side, people observe that both humans and LLMs are obviously capable of behaving like, well, not that. The latter group accuses the former of head-in-the-clouds abstract theorizing gone off the rails, while the former accuses the latter of mindlessly assuming that the future will always be the same as the present, rather than trying to understand things. “Alas, the power-seeking ruthless consequentialist AIs are still coming,” sigh the former. “Just you wait.”

As it happens, I’m basically in that “alas, just you wait” camp, expecting ruthless future AIs. But my camp faces a real question: what exactly is it about human brains^[1] that allows them to not always act like power-seeking ruthless consequentialists? I find that existing explanations in the discourse—e.g. “ah but humans just aren’t smart and reflective enough”, or evolved modularity, or shard theory, etc.—to be wrong, handwavy, or otherwise unsatisfying.

So in this post, I offer my own explanation of why “agent foundations” toy models fail to describe humans, centering around a particular non-“behaviorist” RL reward function in human brains that I call Approval Reward, which plays an outsized role in human sociality, morality, and self-image. And then the alignment culture clash above amounts to the two camps having opposite predictions about whether future powerful AIs will have something like Approval Reward (like humans, and today’s LLMs), or not (like utility-maximizers).

(You can read this post as pushing back against pessimists, by offering a hopeful exploration of a possible future path around technical blockers to alignment. Or you can read this post as pushing back against optimists, by “explaining away” the otherwise-reassuring observation that humans and LLMs don't act like psychos 100% of the time.)

Finally, with that background, I’ll go through six more specific areas where “alignment-is-hard” researchers (like me) make claims about what’s “natural” for future AI, that seem quite bizarre from the perspective of human intuitions, and conversely where human intuitions are quite bizarre from the perspective of agent foundations toy models. All these examples, I argue, revolve around Approval Reward. They are:

• 1. The human intuition that it’s normal and good for one’s goals & values to change over the years
• 2. The human intuition that ego-syntonic “desires” come from a fundamentally different place than “urges”
• 3. The human intuition that kindness, deference, and corrigibility are natural
• 4. The human intuition that unorthodox consequentialist planning is rare and sus
• 5. The human intuition that societal norms and institutions are mostly stably self-enforcing
• 6. The human intuition that treating other humans as a resource to be callously manipulated and exploited, just like a car engine or any other complex mechanism in their environment, is a weird anomaly rather than the obvious default

0. Background

0.1 Human social instincts and “Approval Reward”

As I discussed in Neuroscience of human social instincts: a sketch (2024), we should view the brain as having a reinforcement learning (RL) reward function, which says that pain is bad, eating-when-hungry is good, and dozens of other things (sometimes called “innate drives” or “primary rewards”). I argued that part of the reward function was a thing I called the “compassion / spite circuit”, centered around a small number of (hypothesized) cell groups in the hypothalamus, and I sketched some of its effects.

Then last month in Social drives 1: “Sympathy Reward”, from compassion to dehumanization and Social drives 2: “Approval Reward”, from norm-enforcement to status-seeking, I dove into the effects of this “compassion / spite circuit” more systematically.

And now in this post, I’ll elaborate on the connections between “Approval Reward” and AI technical alignment.

“Approval Reward” fires most strongly in situations where I’m interacting with another person (call her Zoe), and I’m paying attention to Zoe, and Zoe is also paying attention to me. If Zoe seems to be feeling good, that makes me feel good, and if Zoe is feeling bad, that makes me feel bad. Thanks to these brain reward signals, I want Zoe to like me, and to like what I’m doing. And then Approval Reward generalizes from those situations to other similar ones, including where Zoe is not physically present, but I imagine what she would think of me. It sends positive or negative reward signals in those cases too.

As I argue in Social drives 2, this “Approval Reward” leads to a wide array of effects, including credit-seeking, blame-avoidance, and status-seeking. It also leads not only to picking up and following social norms, but also to taking pride in following those norms, even when nobody is watching, and to shunning and punishing those who violate them.

This is not what normally happens with RL reward functions! For example, you might be wondering: “Suppose I surreptitiously^[2] press a reward button when I notice my robot following rules. Wouldn’t that likewise lead to my robot having a proud, self-reflective, ego-syntonic sense that rule-following is good?” I claim the answer is: no, it would lead to something more like an object-level “desire to be noticed following the rules”, with a sociopathic, deceptive, ruthless undercurrent.^[3]

I argue in Social drives 2 that Approval Reward is overwhelmingly important to most people’s lives and psyches, probably triggering reward signals thousands of times a day, including when nobody is around but you’re still thinking thoughts and taking actions that your friends and idols would approve of.

Approval Reward is so central and ubiquitous to (almost) everyone’s world, that it’s difficult and unintuitive to imagine its absence—we’re much like the proverbial fish who puzzles over what this alleged thing called “water” is.

…Meanwhile, a major school of thought in AI alignment implicitly assumes that future powerful AGIs / ASIs will almost definitely lack Approval Reward altogether, and therefore AGIs / ASIs will behave in ways that seem (to normal people) quite bizarre, unintuitive, and psychopathic.

The differing implicit assumption about whether Approval Reward will be present versus absent in AGI / ASI is (I claim) upstream of many central optimist-pessimist disagreements on how hard technical AGI alignment will be. My goal in this post is to clarify the nature of this disagreement, via six example intuitions that seem natural to humans but are rejected by “alignment-is-hard” alignment researchers. All these examples centrally involve Approval Reward.

0.2 Hang on, will future powerful AGI / ASI “by default” lack Approval Reward altogether?

This post is mainly making a narrow point that the proposition “alignment is hard” is closely connected to the proposition “AGI will lack Approval Reward”. But an obvious follow-up question is: are both of these propositions true? Or are they both false?

Here’s how I see things, in brief, broken down into three cases:

If AGI / ASI will be based on LLMs: Humans have Approval Reward (arguably apart from some sociopaths etc.). And LLMs are substantially sculpted by human imitation (see my post Foom & Doom §2.3). Thus, unsurprisingly, LLMs also display behaviors typical of Approval Reward, at least to some extent. Many people see this as a reason for hope that technical alignment might be solvable. But then the alignment-is-hard people have various counterarguments, to the effect that these Approval-Reward-ish LLM behaviors are fake, and/or brittle, and/or unstable, and that they will definitely break down as LLMs get more powerful. The cautious-optimists generally find those pessimistic arguments confusing (example).

Who’s right? Beats me. It’s out-of-scope for this post, and anyway I personally feel unable to participate in that debate because I don’t expect LLMs to scale to AGI in the first place.^[4]

If AGI / ASI will be based on RL agents (or similar), as expected by David Silver & Rich Sutton, Yann LeCun, and myself (“brain-like AGI”), among others, then the answer is clear: There will be no Approval Reward at all, unless the programmers explicitly put it into the reward function source code. And will they do that? We might (or might not) hope that they do, but it should definitely not be our “default” expectation, the way things are looking today.  For example, we don’t even know how to do that, and it’s quite different from anything in the literature. (RL agents in the literature almost universally have “behaviorist” reward functions.) We haven’t even pinned down all the details of how Approval Reward works in humans. And even if we do, there will be technical challenges to making it work similarly in AIs—which, for example, do not grow up with a human body at human speed in a human society. And even if it were technically possible, and a good idea, to put in Approval Reward, there are competitiveness issues and other barriers to it actually happening. More on all this in future posts.

If AGI / ASI will wind up like “rational agents”, “utility maximizers”, or related: Here the situation seems even clearer: as far as I can tell, under common assumptions, it’s not even possible to fit Approval Reward into these kinds of frameworks, such that it would lead to the effects that we expect from human experience. No wonder human intuitions and “agent foundations” people tend to talk past each other!

0.3 Where do self-reflective (meta)preferences come from?

This idea will come up over and over as we proceed, so I’ll address it up front:

In the context of utility-maximizers etc., the starting point is generally that desires are associated with object-level things (whether due to the reward signals or the utility function). And from there, the meta-preferences will naturally line up with the object-level preferences.

After all, consider: what’s the main effect of ‘me wanting X’? It’s ‘me getting X’. So if getting X is good, then ‘me wanting X’ is also good. Thus, means-end reasoning (or anything functionally equivalent, e.g. RL backchaining) will echo object-level desires into corresponding self-reflective meta-level desires. And this is the only place that those meta-level desires come from.

By contrast, in humans, self-reflective (meta)preferences mostly (though not exclusively) come from Approval Reward. By and large, our “true”, endorsed, ego-syntonic desires are approximately whatever kinds of desires would impress our friends and idols (see previous post §3.1).

…OK, finally, let’s jump into those “6 reasons” that I promised in the title!

1. The human intuition that it’s normal and good for one’s goals & values to change over the years

In human experience, it is totally normal and good for desires to change over time. Not always, but often. Hence emotive conjugations like

• “I was enculturated, you got indoctrinated, he got brainwashed”
• “I came to a new realization, you changed your mind, he failed to follow through on his plans and commitments”
• “I’m open-minded, you’re persuadable, he’s a flip-flopper”

…And so on. Anyway, openness-to-change, in the right context, is great. Indeed, even our meta-preferences concerning desire-changes are themselves subject to change, and we’re generally OK with that too.^[5]

Whereas if you’re thinking about an AI agent with foresight, planning, and situational awareness (whether it’s a utility maximizer, or a model-based RL agent^[6], etc.), this kind of preference is a weird anomaly, not a normal expectation. The default instead is instrumental convergence: if I want to cure cancer, then I (incidentally) want to continue wanting to cure cancer until it’s cured.

Why the difference? Well, it comes right from that diagram in §0.3 just above. For Approval-Reward-free AGIs (which I see as “default”), their self-reflective (meta)desires are subservient to their object-level desires.

Goal-preservation follows: if the AGI wants object-level-thing X to happen next week, then it wants to want X right now, and it wants to still want X tomorrow.

By contrast, in humans, self-reflective preferences mostly come from Approval Reward. By and large, our “true”, endorsed desires are approximately whatever kinds of desires would impress our friends and idols, if they could read our minds. (They can’t actually read our minds—but our own reward function can!)

This pathway does not generate any particular force for desire preservation.^[7] If our friends and idols would be impressed by desires that change over time, then that’s generally what we want for ourselves as well.

2. The human intuition that ego-syntonic “desires” come from a fundamentally different place than “urges”

In human experience, it is totally normal and expected to want X (e.g. candy), but not want to want X. Likewise, it is totally normal and expected to dislike X (e.g. homework), but want to like it.

And moreover, we have a deep intuitive sense that the self-reflective meta-level ego-syntonic “desires” are coming from a fundamentally different place as the object-level “urges” like eating-when-hungry. For example, in a recent conversation, a high-level AI safety funder confidently told me that urges come from human nature while desires come from “reason”. Similarly, Jeff Hawkins dismisses AGI extinction risk partly on the (incorrect) grounds that urges come from the brainstem while desires come from the neocortex (see my Intro Series §3.6 for why he’s wrong and incoherent on this point).

In a very narrow sense, there’s actually a kernel of truth to the idea that, in humans, urges and desires come from different sources. As in Social Drives 2 and §0.3 above, one part of the RL reward function is Approval Reward, and is the primary (though not exclusive) source of ego-syntonic desires. Everything else in the reward function mostly gives rise to urges.

But this whole way of thinking is bizarre and inapplicable from the perspective of Approval-Reward-free AI futures—utility maximizers, “default” RL systems, etc. There, as above, the starting point is object-level desires; self-reflective desires arise only incidentally.

A related issue is how we think about AGI reflecting on its own desires. How this goes depends strongly on the presence or absence of (something like) Approval Reward.

Start with the former. Humans often have conflicts between ego-syntonic self-reflective desires and ego-dystonic object-level urges, and reflection allows the desires to scheme against the urges, potentially resulting in large behavior changes. If AGI has Approval Reward (or similar), we should expect AGI to undergo those same large changes upon reflection. Or perhaps even larger—after all, AGIs will generally have more affordances for self-modification than humans do.

By contrast, I happen to expect AGIs, by default (in the absence of Approval Reward or similar), to mainly have object-level, non-self-reflective desires. For such AGIs, I don’t expect self-reflection to lead to much desire change. Really, it shouldn’t lead to any change more interesting than pursuing its existing desires more effectively.

(Of course, such an AGI may feel torn between conflicting object-level desires, but I don’t think that leads to the kinds of internal battles that we’re used to from humans.^[8])

(To be clear, reflection in Approval-Reward-free AGIs might still have “complications” of other sorts, such as ontological crises.)

3. The human intuition that helpfulness, deference, and corrigibility are natural

This human intuition comes straight from Approval Reward, which is absolutely central in human intuitions, and leads to us caring about whether others would approve of our actions (even if they’re not watching), taking pride in our virtues, and various other things that distinguish neurotypical people from sociopaths.

As an example, here’s Paul Christiano: “I think that normal people [would say]: ‘If we are trying to help some creatures, but those creatures really dislike the proposed way we are “helping” them, then we should try a different tactic for helping them.’”

He’s right: normal people would definitely say that, and our human Approval Reward is why we would say that. And if AGI likewise has Approval Reward (or something like it), then the AGI would presumably share that intuition.

On the other hand, if Approval Reward is not part of AGI / ASI, then we’re instead in the “corrigibility is anti-natural” school of thought in AI alignment. As an example of that school of thought, see Why Corrigibility is Hard and Important.

4. The human intuition that unorthodox consequentialist planning is rare and sus

Obviously, humans can make long-term plans to accomplish distant goals—for example, an 18-year-old could plan to become a doctor in 15 years, and immediately move this plan forward via sensible consequentialist actions, like taking a chemistry class.

How does that work in the 18yo’s brain? Obviously not via anything like RL techniques that we know and love in AI today—for example, it does not work by episodic RL with an absurdly-close-to-unity discount factor that allows for 15-year time horizons. Indeed, the discount factor / time horizon is clearly irrelevant here! This 18yo has never become a doctor before!

Instead, there has to be something motivating the 18yo right now to take appropriate actions towards becoming a doctor. And in practice, I claim that that “something” is almost always an immediate Approval Reward signal.

Here’s another example. Consider someone saving money today to buy a car in three months. You might think that they’re doing something unpleasant now, for a reward later. But I claim that that’s unlikely. Granted, saving the money has immediately-unpleasant aspects! But saving the money also has even stronger immediately-pleasant aspects—namely, that the person feels pride in what they’re doing. They’re probably telling their friends periodically about this great plan they’re working on, and the progress they’ve made. Or if not, they’re probably at least imagining doing so.

So saving the money is not doing an unpleasant thing now for a benefit later. Rather, the pleasant feeling starts immediately, thanks to (usually) Approval Reward.

Moreover, everyone has gotten very used to this fact about human nature. Thus, doing the first step of a long-term plan, without Approval Reward for that first step, is so rare that people generally regard it as highly suspicious. They generally assume that there must be an Approval Reward. And if they can’t figure out what it is, then there’s something important about the situation that you’re not telling them. …Or maybe they’ll assume that you’re a Machiavellian sociopath.

As an example, I like to bring up Earning To Give (EtG) in Effective Altruism, the idea of getting a higher-paying job in order to earn money and give it to charity. If you tell a normal non-nerdy person about EtG, they’ll generally assume that it’s an obvious lie, and that the person actually wants the higher-paying job for its perks and status. That’s how weird it is—it doesn’t even cross most people’s minds that someone is actually doing a socially-frowned-upon plan because of its expected long-term consequences, unless the person is a psycho. …Well, that’s less true now than a decade ago; EtG has become more common, probably because (you guessed it) there’s now a community in which EtG is socially admirable.

Related: there’s a fiction trope that basically only villains are allowed to make out-of-the-box plans and display intelligence. The normal way to write a hero in a work of fiction is to have conflicts between doing things that have strong immediate social approval, versus doing things for other reasons (e.g. fear, hunger, logic(!)), and to have the former win out over the latter in the mind of the hero. And then the hero pursues the immediate-social-approval option with such gusto that everyone lives happily ever after.^[9]

That’s all in the human world. Meanwhile in AI, the alignment-is-hard thinkers like me generally expect that future powerful AIs will lack Approval Reward, or anything like it. Instead, they generally assume that the agent will have preferences about the future, and make decisions so as to bring about those preferences, not just as a tie-breaker on the margin, but as the main event. Hence instrumental convergence. I think this is exactly the right assumption (in the absence of a specific designed mechanism to prevent that), but I think people react with disbelief when we start describing how these AI agents behave, since it’s so different from humans.

…Well, different from most humans. Sociopaths can be a bit more like that (in certain ways). Ditto people who are unusually “agentic”. And by the way, how do you help a person become “agentic”? You guessed it: a key ingredient is calling out “being agentic” as a meta-level behavioral pattern, and indicating to this person that following this meta-level pattern will get social approval! (Or at least, that it won’t get social disapproval.)

5. The human intuition that societal norms and institutions are mostly stably self-enforcing

5.1 Detour into “Security-Mindset Institution Design”

There’s an attitude, common in the crypto world, that we might call “Security-Mindset Institution Design”. You assume that every surface is an attack surface. You assume that everyone is a potential thief and traitor. You assume that any group of people might be colluding against any other group of people. And so on.

It is extremely hard to get anything at all done in “Security-Mindset Institution Design”, especially when you need to interface with the real-world, with all its rich complexities that cannot be bounded by cryptographic protocols and decentralized verification. For example, crypto Decentralized Autonomous Organizations (DAOs) don’t seem to have done much of note in their decade of existence, apart from on-chain projects, and occasionally getting catastrophically hacked. Polymarket has a nice on-chain system, right up until the moment that a prediction market needs to resolve, and even this tiny bit of contact with the real world seems to be a problematic source of vulnerabilities.

If you extend this “Security Mindset Institution Design” attitude to an actual fully-real-world government and economy, it would be beyond hopeless. Oh, you have an alarm system in your house? Why do you trust that the alarm system company, or its installer, is not out to get you? Oh, the company has a good reputation? According to who? And how do you know they’re not in cahoots too?

…That’s just one tiny microcosm of a universal issue. Who has physical access to weapons? Why don’t those people collude to set their own taxes to zero and to raise everyone else’s? Who sets government policy, and what if those people collude against everyone else? Or even if they don’t collude, are they vulnerable to blackmail? Who counts the votes, and will they join together and start soliciting bribes? Who coded the website to collect taxes, and why do we trust them not to steal tons of money and run off to Dubai?

…OK, you get the idea. That’s the “Security Mindset Institution Design” perspective.

5.2 The load-bearing ingredient in human society is not Security-Mindset Institution Design, but rather good-enough institutions plus almost-universal human innate Approval Reward

Meanwhile, ordinary readers^[10] might be shaking their heads and saying:

“Man, what kind of strange alien world is being described in that subsection above? High-trust societies with robust functional institutions are obviously possible! I live in one!”

The wrong answer is: “Security Mindset Institution Design is insanely overkill; rather, using checks and balances to make institutions stable against defectors is in fact a very solvable problem in the real world.”

Why is that the wrong answer? Well for one thing, if you look around the real world, even well-functioning institutions are obviously not robust against competent self-interested sociopaths willing to burn the commons for their own interests. For example, I happen to have a high-functioning sociopath ex-boss from long ago. Where is he now? Head of research at a major USA research university, and occasional government appointee wielding immense power. Or just look at how Donald Trump has been systematically working to undermine any aspect of society or government that might oppose his whims or correct his lies.^[11]

For another thing, abundant “nation-building” experience shows that you cannot simply bestow a “good” government constitution onto a deeply corrupt and low-trust society, and expect the society to instantly transform into Switzerland. Institutions and laws are not enough. There’s also an arduous and fraught process of getting to the right social norms. Which brings us to:

The right answer is, you guessed it, human Approval Reward, a consequence of which is that almost all humans are intrinsically motivated to follow and enforce social norms. The word “intrinsically” is important here. I’m not talking about transactionally following norms when the selfish benefit outweighs the selfish cost, while constantly energetically searching for norm-violating strategies that might change that calculus. Rather, people take pride in following the norms, and in punishing those who violate them.

Obviously, any possible system of norms and institutions will be vastly easier to stabilize when, no matter what the norm is, you can get up to ≈99% of the population proudly adopting it, and then spending their own resources to root out, punish, and shame the 1% of people who undermine it.

In a world like that, it is hard but doable to get into a stable situation where 99% of cops aren’t corrupt, and 99% of judges aren’t corrupt, and 99% of people in the military with physical access to weapons aren’t corrupt, and 99% of IRS agents aren’t corrupt, etc. The last 1% will still create problems, but the other 99% have a fighting chance to keep things under control. Bad apples can be discovered and tossed out. Chains of trust can percolate.

5.3 Upshot

Something like 99% of humans are intrinsically motivated to follow and enforce norms, with the rest being sociopaths and similar. What about future AGIs? As discussed in §0.2, my own expectation is that 0% of them will be intrinsically motivated to follow and enforce norms. When those sociopathic AGIs grow in number and power, it takes us from the familiar world of §5.2 to the paranoid insanity world of §5.1.

In that world, we really shouldn’t be using the word “norm” at all—it’s just misleading baggage. We should be talking about rules that are stably self-enforcing against defectors, where the “defectors” are of course allowed to include those who are supposed to be doing the enforcement, and where the “defectors” might also include broad coalitions coordinating to jump into a new equilibrium that Pareto-benefits them all. We do not have such self-enforcing rules today. Not even close. And we never have. And inventing such rules is a pipe dream.^[12]

The flip side, of course, is that if we figure out how to ensure that almost all AGIs are intrinsically motivated to follow and enforce norms, then it’s the pessimists who are invoking a misleading mental image if they lean on §5.1 intuitions.

6. The human intuition that treating other humans as a resource to be callously manipulated and exploited, just like a car engine or any other complex mechanism in their environment, is a weird anomaly rather than the obvious default

Click over to Foom & Doom §2.3.4—“The naturalness of egregious scheming: some intuitions” to read this part.

7. Conclusion

(Homework: can you think of more examples?)

I want to reiterate that my main point in this post is not

Alignment is hard and we’re doomed because future AIs definitely won’t have Approval Reward (or something similar).

but rather

There’s a QUESTION of whether or not alignment is hard and we’re doomed, and many cruxes for this question seem to be downstream of the narrower question of whether future AIs will have Approval Reward (or something similar) (§0.2). I am surfacing this latent uber-crux to help advance the discussion.

For my part, I’m obviously very interested in the question of whether we can and should put Approval Reward (and Sympathy Reward) into Brain-Like AGI, and what might go right and wrong if we do so. More on that in (hopefully) upcoming posts!

Thanks Seth Herd, Linda Linsefors, Charlie Steiner, Simon Skade, Jeremy Gillen, and Justis Mills for critical comments on earlier drafts.

1. ^{^}

   …and by extension today’s LLMs, which (I claim) get their powers mainly from imitating humans.

2. ^{^}

   I said “surreptitiously” here because if you ostentatiously press a reward button, in a way that the robot can see, then the robot would presumably wind up wanting the reward button to be pressed, which eventually leads to the robot grabbing the reward button etc. See Reward button alignment.

3. ^{^}

   See Perils of under- vs over-sculpting AGI desires, especially §7.2, for why the “nice” desire would not even be temporarily learned, and if it were it would be promptly unlearned; and see “Behaviorist” RL reward functions lead to scheming for some related intuitions; and see §3.2 of the Approval Reward post for why those don’t apply to (non-behaviorist) Approval Reward.

4. ^{^}

   My own take, which I won’t defend here, is that this whole debate is cursed, and both sides are confused, because LLMs cannot scale to AGI. I think the AGI concerns really are unsolved, and I think that LLM techniques really are potentially-safe, but they are potentially-safe for the very reason that they won’t lead to AGI. I think “LLM AGI” is an incoherent contradiction, like “square circle”, and one side of the debate has a mental image of “square thing (but I guess it’s somehow also a circle)”, and the other side of the debate has a mental image of “circle (but I guess it’s somehow also square)”, so no wonder they talk past each other. So that’s how things seem to me right now. Maybe I’m wrong!! But anyway, that’s why I feel unable to take a side in this particular debate. I’ll leave it to others. See also: Foom & Doom §2.9.1.

5. ^{^}

   …as long as the meta-preferences-about-desire-changes are changing in a way that seems good according to those same meta-preferences themselves—growth good, brainwashing bad, etc.

6. ^{^}

   Possible objection: “If the RL agent has lots of past experience of its reward function periodically changing, won’t it learn that this is good?” My answer: No. At least for the kind of model-based RL agent that I generally think about, the reward function creates desires, and the desires guide plans and actions. So at any given time, there are still desires, and if these desires concern the state of the world in the future, then the instrumental convergence argument for goal-preservation goes through as usual. I see no process by which past history of reward function changes should make an agent OK with further reward function changes going forward.

   (But note that the instrumental convergence argument makes model-based RL agents want to preserve their current desires, not their current reward function. For example, if an agent has a wireheading desire to get reward, it will want to self-modify to preserve this desire while changing the reward function to “return +∞”.)

7. ^{^}

   …At least to a first approximation. Here are some technicalities: (1) Other pathways also exist, and can generate a force for desire preservation. (2) There’s also a loopy thing where Approval Reward influences self-reflective desires, which in turn influence Approval Reward, e.g. by changing who you admire. (See Approval Reward post §5–§6.) This can (mildly) lock in desires. (3) Even Approval Reward itself leads not only to “proud feeling about what I’m up to right now” (Approval Reward post §3.2), which does not particularly induce desire-preservation, but also to “desire to actually interact with and impress a real live human sometime in the future”, which is on the left side of that figure in §0.3, and which (being consequentialist) does induce desire-preservation and the other instrumental convergence stuff.

8. ^{^}

   If an Approval-Reward-free AGI wants X and wants Y, then it could get more X by no longer wanting Y, and it could get more Y by no longer wanting X. So there’s a possibility that AGI reflection could lead to “total victory” where one desire erases another. But I (tentatively) think that’s unlikely, and that the more likely outcome is that the AGI would continue to want both X and Y, and to split its time and resources between them. A big part of my intuition is: you can theoretically have a consequentialist utility-maximizer with utility function $U=\log \left(X\right)+\log \left(Y\right)$, and it will generally split its time between X and Y forever, and this agent is reflectively stable. (The logarithm ensures that X and Y have diminishing returns. Or if that’s not diminishing enough, consider $U=\log \log X+\log \log Y$, etc.)

9. ^{^}

   To show how widespread this is, I don’t want to cherry-pick, so my two examples will be the two most recent movies that I happen to have watched, as I’m sitting down to write this paragraph. These are: Avengers: Infinity War & Ant-Man and the Wasp. (Don’t judge, I like watching dumb action movies while I exercise.)

   Spoilers for the Marvel Cinematic Universe film series (pre-2020) below:

   The former has a wonderful example. The heroes can definitely save trillions of lives by allowing their friend Vision to sacrifice his life, which by the way he is begging to do. They refuse, instead trying to save Vision and save the trillions of lives. As it turns out, they fail, and both Vision and the trillions of innocent bystanders wind up dead. Even so, this decision is portrayed as good and proper heroic behavior, and is never second-guessed even after the failure. (Note that “Helping a friend in need who is standing right there” has very strong immediate social approval for reasons explained in §6 of Social drives 1 (“Sympathy Reward strength as a character trait, and the Copenhagen Interpretation of Ethics”).) (Don’t worry, in a sequel, the plucky heroes travel back in time to save the trillions of innocent bystanders after all.)

   In the latter movie, nobody does anything quite as outrageous as that, but it’s still true that pretty much every major plot point involves the protagonists risking themselves, or their freedom, or the lives of unseen or unsympathetic third parties, in order to help their friends or family in need—which, again, has very strong immediate social approval.

10. ^{^}

    And @Matthew Barnett! This whole section is based on (and partly copied from) a comment thread last year between him and me.

11. ^{^}

    …in a terrifying escalation of a long tradition that both USA parties have partaken in. E.g. if you want examples of the Biden administration recklessly damaging longstanding institutional norms, see 1, 2. (Pretty please don’t argue about politics in the comments section.)

12. ^{^}

    Superintelligences might be able to design such rules amongst themselves, for all I know, although it would probably involve human-incompatible things like “merging” (jointly creating a successor ASI then shutting down). Or we might just get a unipolar outcome in the first place (e.g. many copies of one ASI with the same non-indexical goal), for reasons discussed in my post Foom & Doom §1.8.7.

2025-12-04 02:29:15

Published on December 3, 2025 6:29 PM GMT

Mechanistic Interpretability

Many of you will be familiar with the following section. Please skip through to the next.

The field of mechanistic interpretability (MI) is not a single, monolithic research program but rather a rapidly evolving collection of methods, tools, and research programs. These are united by the shared ambition of reverse-engineering NN computations and, though lacking a comprehensive uniform methodology, typically apply tools of causal analysis to understand a model from the bottom up.

MI research centres around a set of postulates. One central postulate is that NN representations can in principle be decomposed into interpretable "features"—fundamental units that "cannot be further disentangled into smaller, distinct factors"—and that these are often encoded linearly as directions in activation space. Further work has shown that NNs in fact combine multiple features into the same neuron—a phenomenon called superposition.

Some examples of mechanistic techniques include the following:

• Linear Probes: Simple models (usually linear classifiers) are trained to predict a specific property (e.g., the part-of-speech of a word) from a model's internal activations. The success or failure of a probe at a given layer is used to infer whether that information is explicitly represented there.
• Logit Lens: This technique applies the final decoding layer of the model to intermediate activations, to observe how its prediction evolves layer-by-layer.
• Sparse Autoencoders: These attempt to disentangle a NN's features by expressing them in a higher-dimensional space under a sparsity penalty, effectively expanding the computation into linear combinations of sparsely activating features.
• Activation patching: This technique attempts to isolate circuits of the network responsible for specific behaviours, by replacing a circuit active for a specific output with another, to test the counterfactual hypothesis.

The Causal-Mechanistic Paradigm

More recently, MI has been developing from a pre-paradigmatic assortment of techniques into something more substantial. It has been the subject of a comprehensive review paper, has been given a theoretical grounding via causal abstractions, and has more recently been given a philosophical treatment via the philosophy of explanations .

In particular, this philosophical treatment characterizes MI as the search for explanations that satisfy the following conditions:

1. Causal–Mechanistic - providing step-by-step causal chains of how the computation is realized. This contrasts with attribution methods like saliency maps, which are primarily correlational. A saliency map might show that pixels corresponding to a cat's whiskers are "important" for a classification, but it doesn't explain the mechanism of how the model processes that whisker information through subsequent layers to arrive at its decision.
2. Ontic - MI researchers believe they are discovering "real" structures within the model. This differs from a purely epistemic approach, which might produce a useful analogy or simplified story that helps human understanding but doesn't claim to uncover what is happening in reality. The search for "features" as fundamental units in activation space is a standard ontic commitment of the field.
3. Falsifiable - MI explanations are framed as testable hypotheses that can be empirically refuted. The claim that "this specific set of neurons and attention heads forms a circuit for detecting syntax" is falsifiable. One can perform a causal intervention—such as activation patching or ablating the circuit—and observe if the model's syntactic capabilities break in a predictable way. This contrasts with unfalsifiable, post-hoc stories that cannot be rigorously tested.
4. Model-level - The focus of MI is on the neural network itself—its weights, activations, and architecture. This is distinct from system-level analysis, which might examine the behaviour of an entire deployed product (e.g., a chatbot integrated with search tools and a chain-of-thought prompting wrapper). A system-level explanation might attribute a behavior to the prompt, whereas a model-level explanation seeks the mechanism within the neural network's computational graph.

Leaving aside questions regarding the aptness of this philosophical characterization, we focus here on the causal–mechanistic nature of the explanations that mechanistic interpretability produces. 

We define the causal-mechanistic paradigm as the belief that we can decompose AI systems into smaller causal components by analysing their computational structure, and from these components reconstruct precise explanations of AI system behaviour.

From Bereska & Gavves (2024) [Emphasis ours]: 

"The theory of causality (Pearl, 2009) provides a mathematically precise language for mechanistic interpretability, forming the foundation for understanding high-level semantics in neural representations (Geiger et al., 2023a). Treating neural networks as causal models involves considering the compute graph as the causal graph, allowing for precise interventions and examining individual parameters' roles (McGrath et al., 2023)." 

A direct relationship is drawn between the inner structure of an AI system (i.e., the compute graph) and the methods (i.e., interventions upon the corresponding causal graph) that we use to predict the relevant behaviors. That is, we can understand the relevant outcomes of an AI system if and only if we understand its inner structure.

Multiple realizability

Two recent works indicate a fundamental problem in how we interpret NNs.

Bailey et al. (2024) tested a variety of latent space monitoring approaches designed to prevent networks from outputting harmful content. These included sparse autoencoders, linear and MLP probes, and out-of-distribution detectors. All use the internal activations of the model to identify where harmful output is generated. All embody the broader assumption that understanding internal structure allows for behavioural prediction and control.

They developed obfuscation attacks—joint optimization procedures that simultaneously preserve harmful behavioural outputs while making the model's internal activations appear benign to latent-space monitors. These attacks used both adversarial suffixes (optimized text appended to prompts) and embedding-space perturbations. These attacks systematically evaded all tested latent-space monitoring techniques—achieving near-zero recall rates on harmfulness detection while maintaining high jailbreaking efficacy (>90%).

Even more worryingly, they demonstrated just how robustly a NN can obfuscate its activations. They conducted red-team/blue-team games as follows: in each round, the attacker would first train a new embedding suffix designed to both jailbreak the model and fool the current monitor, then the defender would retrain their monitor against the obfuscated activations from this attack plus all previous attacks. The model was able to successfully obfuscate its activations more than 70 times.

Whilst these results have arisen in a training environment explicitly designed to induce obfuscation, the main conceptual takeaway—and the hypothesis put forward by the authors—is this:

"Models can represent concepts and execute behaviors using a broad set of different activations. That is, neural representations are highly malleable: we can reshape activation patterns in a variety of ways, while preserving a network's behavior."

Other researchers have identified a similar problem.

McGrath et al. (2023) showed how networks can perform self-repair under layer ablation. They performed ablation experiments on Chinchilla 7B, measuring the model's performance on a factual recall task by comparing the results of two approaches:

1. Unembedding (direct effect): This is a typical MI approach, similar to logit lens, it consists of taking the output of the layer and running it through the final unembedding layer in the model's architecture, to track the correlation between each layer's computations and the model's output.
2. Ablation-based (total effect): Here, they effectively "disabled" layers by replacing their activations with those registered in the same layer but under different prompts. They then measured the change in the model output.

They found that these measures disagreed. That is, some layers had a large direct effect on the overall prediction, but when they were removed only a small change in the total effect was recorded.

They subsequently identified two separate effects:

1. Self-repair/Hydra effect: Some downstream attention layers were found to compensate when an upstream one was ablated. These later layers exhibited an increased unembedding effect compared to the non-ablated run.
2. Erasure: Some MLP layers were found to have a negative contribution in the clean run, suppressing certain outputs. When upstream layers were ablated, these MLP layers reduced their suppression, in effect partially restoring the clean-run output.

Compensation was found to typically restore ~70% of the original output. The model was also trained without any form of dropout, which would typically incentivise the model to build alternate computational pathways. These pathways seem to occur naturally, and we offer that these results demonstrate how networks enjoy—in addition to flexibility over their representations—considerable flexibility over the computational pathways they use when processing information.

This presents an obstacle to the causal analysis of neural networks, in which interventions are used to test counterfactual hypotheses and establish genuine causal dependencies.

Summary

Rather than "harmfulness" consisting of a single direction in latent space—or even a discrete set of identifiable circuits—Bailey et al.'s evidence suggests it can be represented through numerous distinct activation patterns, many of which can be found within the distribution of benign representations. Similarly, rather than network behaviors being causally attributable to specific layers, McGrath et al.'s experiments show that such behaviors can be realized in a variety of ways, allowing networks to evade intervention efforts.

Following similar phenomena in the philosophy of mind and science, we might call this the multiple realizability of neural computations.

Such multiple realizability is deeply concerning. We submit that these results should be viewed not simply as technical challenges to be overcome through better monitoring techniques, but as indicating broader limits to the causal-mechanistic paradigm's utility in safety work. We further believe that these cases form part of a developing threat model: substrate-flexible risk, as described in the following post. As NNs become ever more capable and their latent spaces inevitably become larger, we anticipate substrate-flexible risks to become increasingly significant for the AI safety landscape.

2025-12-04 01:23:31

Published on December 3, 2025 5:23 PM GMT

A team at Google has substantially advanced the theory of embedded agency with a grain of truth (GOT), including new developments on reflective oracles and an interesting alternative construction (the "Reflective Universal Inductor" or RUI).

(I was not involved in this work) 

2025-12-04 01:14:41

Published on December 3, 2025 5:14 PM GMT

TL;DR: Given how humans form group identities via shared memory infrastructures, and given that AI is becoming a central part of those infrastructures, we should expect some degree of human-AI identity coupling (non‑zero) to emerge in many contexts.

Epistemic status: This post borrows frameworks from Benedict Anderson and Maurice Halbwachs (via an Art History dissertation by my mother) and applies the anthropological theory to AI systems.

"Identity coupling" definition

• Identifying with a distinct being or subsystem that reciprocates via shared context.
  • "Identifying with" here means internal world-models and goal structures represent the counterparty as part of their own ingroup rather than a neutral external object.
  • Identity coupling from humans to AI is emergent along a spectrum, e.g from consuming AI-generated text and videos (low identity) to intimate life planning or simulated bonding (high identity).
  • Identity coupling from AI to humans is emergent along a spectrum, e.g from humans appearing in training data (low identity), to individual personalised human inputs incorporated in minute-by-minute operation (high identity).
  • Identity coupling could be measured by self-other overlap.

Anthropological primer

1. The acclaimed work Imagined Communities by Benedict Anderson examined the origin and spread of nationalism throughout different geographies across the world.
2. Benedict Anderson described how the process of creating nations has taken place over time, in particular following the emergence of the modern nation-state.
3. Anderson was primarily concerned with the role of language, in both its spoken and written form, in the creation and reinforcement of national identity — exploring how the emergence of mass publication of works in the vernacular allowed common languages to develop across nations connecting hitherto unconnected individuals in this common tongue.
4. However, Anderson opened his work with a discussion of the role of a specific form of public art: cenotaphs and tombs of Unknown Soldiers. Anderson argues that despite being “void…of identifiable mortal remains or immortal souls” these structures are however packed full of nationalist meaning
5. Anderson’s focus on monuments with a specific memorial function underlines a key purpose of monuments as a whole, as evinced in the etymological root of the word ‘monument’, that is that they exist to commemorate.
6. Anderson’s Proposition:^[1] The choice of what is memorialised in the public sphere is an instrument by which to construct the memories of the communities in which they are displayed.
7. Memories are given material form, consumed by publics and then integrated into their memory.
8. To qualify and enrich (6) and (7): In On Collective Memory (1992) Maurice Halbwachs discusses memory formation within families, religious groups and social classes but his theories can equally be applied to nations. As memory formation is — in Halbwachs mind — a collective activity, it is instrumental in the formation of group identities.
9. Halbwachs’ Mechanism:^[2] When individuals belong to a particular group, or indeed join that group, they form their memories within that group’s framework.
10. So for Halbwachs individuals’ memories are amalgams of actual lived memories set within the wider framework of the group. This framework shapes the memories which in turn become part of the framework that shapes further memories. In the same way that notable personal events are remembered and shaped within families, so public monuments serve to ‘remember’ and shape public memories.

Human-AI identity coupling is emergent

The above lays the foundation for the following idea:

1. We can use Halbwachs’ Mechanism to consider the group that encompasses all of humanity. A subset of human memories are formed within this framework.^[3]
2. In this sense, returning to Anderson’s Proposition, humanity is an “Imagined Community”. The choice of what we memorialise is an instrument which constructs the memories of the community (humanity).
3. Furthermore, we might form a composite group of humanity plus Large Language Model chatbots^[4] — in my terms this is a “human-LLM” composite.
4. Through chat interfaces, humans and LLMs share a framework for memory formation. Memories are integrated by humans via standard memory mechanisms, while memories are integrated by LLMs either literally as one-to-one “conversation context”, or in three steps by way of first being integrated by a human, next publicised by the human in a form available to future LLMs as training data, and finally as knowledge integrated by the LLM during training. Unlike Anderson's silent monuments, which require the human to do all of the imagining, the LLM acts as an active monument. It processes collective memory alongside the human, effectively becoming a participant in the group rather than just an object of it.
5. Therefore to this group we can again apply Halbwach’s Mechanism but in a different sense: this time to comment on how within the group memory formation is a collective activity. Memories (or “training data”) are co-created between humans and LLMs (or, more generally, Artificial Intelligence) and that is instrumental in the formation of group identities.
6. Non-zero collective identity (or in my terms — “identity coupling”) between humans and artificial intelligence is an emergent outcome of how we form collective identities around shared memory infrastructures, and how deeply AI is being embedded into those infrastructures.

If you'd like future essays by email, subscribe to my Substack, you can also find me on X.

1. ^{^}

   Labelling my own

2. ^{^}

   Labelling my own

3. ^{^}

   For example related to narratives such as human rights, climate change, world peace, or space travel.

4. ^{^}

   This can also apply to future AI systems assuming that LLMs are superseded.

2025-12-04 00:31:21

Published on December 3, 2025 4:31 PM GMT

Some podcasts are self-recommending on the ‘yep, I’m going to be breaking this one down’ level. This was very clearly one of those. So here we go.

As usual for podcast posts, the baseline bullet points describe key points made, and then the nested statements are my commentary.

If I am quoting directly I use quote marks, otherwise assume paraphrases.

What are the main takeaways?

1. Ilya thinks training in its current form will peter out, that we are returning to an age of research where progress requires more substantially new ideas.
2. SSI is a research organization. It tries various things. Not having a product lets it punch well above its fundraising weight in compute and effective resources.
    

• Ilya has 5-20 year timelines to a potentially superintelligent learning model.
• SSI might release a product first after all, but probably not?
• Ilya’s thinking about alignment still seems relatively shallow to me in key ways, but he grasps many important insights and understands he has a problem.
• Ilya essentially despairs of having a substantive plan beyond ‘show everyone the thing as early and often as possible’ and hope for the best. He doesn’t know where to go or how to get there, but does realize he doesn’t know these things, so he’s well ahead of most others.

Afterwards, this post also covers Dwarkesh Patel’s post on the state of AI progress.

Table of Contents

1. Explaining Model Jaggedness.
2. Emotions and value functions.
3. What are we scaling?
4. Why humans generalize better than models.
5. Straight-shooting superintelligence.
6. SSI’s model will learn from deployment.
7. Alignment.
8. “We are squarely an age of research company”.
9. Research taste.
10. Bonus Coverage: Dwarkesh Patel on AI Progress These Days.

Explaining Model Jaggedness

1. Ilya opens by remarking how crazy it is all this (as in AI) is real, it’s all so sci-fi, and yet it’s not felt in other ways so far. Dwarkesh expects this to continue for average people into the singularity, Ilya says no, AI will diffuse and be felt in the economy. Dwarkesh says impact seems smaller than model intelligence implies.
   1. Ilya is right here. Dwarkesh is right that direct impact so far has been smaller than model intelligence implies, but give it time.
2. Ilya says, the models are really good at evals but economic impact lags. The models are buggy, and choices for RL take inspiration from the evals, so the evals are misleading and the humans are essentially reward hacking the evals. And that given they got their scores by studying for tons of hours rather than via intuition, one should expect AIs to underperform their benchmarks.
   1. AIs definitely underperform their benchmarks in terms of general usefulness, even for those companies that do minimal targeting of benchmarks. Overall capabilities lag behind, for various reasons. We still have an impact gap.
3. The super talented student? The one that hardly even needs to practice a specific task to be good? They’ve got ‘it.’ Models don’t have ‘it.’
   1. If anything, models have ‘anti-it.’ They make it up on volume. Sure.

Emotions and value functions

1. Humans train on much less data, but what they know they know ‘more deeply’ somehow, there are mistakes we wouldn’t make. Also evolution can be highly robust, for example the famous case where a guy lost all his emotions and in many ways things remained fine.
   1. People put a lot of emphasis on the ‘I would never’ heuristic, as AIs will sometimes do things ‘a similarly smart person’ would never do, they lack a kind of common sense.
2. So what is the ‘ML analogy for emotions’? Ilya says some kind of value function thing, as in the thing that tells you if you’re doing well versus badly while doing something.
   1. Emotions as value functions makes sense, but they are more information-dense than merely a scalar, and can often point you to things you missed. They do also serve as training reward signals.
   2. I don’t think you ‘need’ emotions for anything other than signaling emotions, if you are otherwise sufficiently aware in context, and don’t need them to do gradient descent.
   3. However in a human, if you knock out the emotions in places where you were otherwise relying on them for information or to resolve uncertainty, you’re going to have a big problem.
   4. I notice an obvious thing to try but it isn’t obvious how to implement it?
3. Ilya has faith in deep learning. There’s nothing it can’t do!

What are we scaling?

1. Data? Parameters? Compute? What else? It’s easier and more reliable to scale up pretraining than to figure out what else to do. But we’ll run out of data soon even if Gemini 3 got more out of this, so now you need to do something else. If you had 100x more scale here would anything be that different? Ilya thinks no.
   1. Sounds like a skill issue, on some level, but yes if you didn’t change anything else then I expect scaling up pretraining further won’t help enough to justify the increased costs in compute and time.
2. RL costs now exceed pretraining costs, because each RL run costs a lot. It’s time to get back to an age of research, trying interesting things and seeing what happens.
   1. I notice I am skeptical of the level of skepticism, also I doubt the research mode ever stopped in the background. The progress will continue. It’s weird how every time someone says ‘we still need some new idea or breakthrough’ there is the implication that this likely never happens again.

Why humans generalize better than models

1. Why do AIs require so much more data than humans to learn? Why don’t models easily pick up on all this stuff humans learn one-shot or in the background?
   1. Humans have richer data than text so the ratio is not as bad as it looks, but primarily because our AI learning techniques are relatively primitive and data inefficient in various ways.
   2. My full answer to how to fix it falls under ‘I don’t do $100m/year jobs for free.’
   3. Also there are ways in which the LLMs learn way better than you realize, and a lot of the tasks humans easily learn are regularized in non-obvious ways.
2. Ilya believes humans being good at learning is mostly not part of some complicated prior, and people’s robustness is really staggering.
   1. I would clarify, not part of a complicated specialized prior. There is also a complicated specialized prior in some key domains, but that is in addition to a very strong learning function.
   2. People are not as robust as Ilya thinks, or most people think.
3. Ilya suggests perhaps human neurons use more compute than we think.

Straight-shooting superintelligence

1. Scaling ‘sucked the air out of the room’ so no one did anything else. Now there are more companies than ideas. You need some compute to bring ideas to life, but not the largest amounts.
   1. You can also think about some potential techniques as ‘this is not worth trying unless you have massive scale.’
2. SSI’s compute all goes into research, none into inference, and they don’t try to build a product, and if you’re doing something different you don’t have to use maximum scale, so their $3 billion that they’ve raised ‘goes a long way’ relative to the competition. Sure OpenAI spends ~$5 billion a year on experiments, but it’s what you do with it.
   1. This is what Ilya has to say in this spot, but there’s merit in it. OpenAI’s experiments are largely about building products now. This transfers to the quest for superintelligence, but not super efficiently.
3. How will SSI make money? Focus on the research, the money will appear.
   1. Matt Levine has answered this one, which is that you make money by being an AI company full of talented researchers, so people give you money.
4. SSI is considering making a product anyway, both to have the product exist and also because timelines might be long.
   1. I mean I guess at some point the ‘we are AI researchers give us money’ strategy starts to look a little suspicious, but let’s not rush into anything.
   2. Remember, Ilya, once you have a product and try to have revenue they’ll evaluate the product and your revenue. If you don’t have one, you’re safe.

SSI’s model will learn from deployment

1. Ilya says even if there is a straight shot to superintelligence deployment would be gradual, you have to ship something first, and that he agrees with Dwarkesh on the importance of continual learning, it would ‘go and be’ various things and learn, superintelligence is not a finished mind.
   1. Learning takes many forms, including continual learning, it can be updating within the mind or otherwise, and so on. See previous podcast discussions.
2. Ilya expects ‘rapid’ economic growth, perhaps ‘very rapid.’ It will vary based on what rules are set in different places.
   1. Rapid means different things to different people, it sounds like Ilya doesn’t have a fixed rate in mind. I interpret it as ‘more than these 2% jokers.’
   2. This vision still seems to think the humans stay in charge. Why?

Alignment

1. Dwarkesh reprises the standard point that if AIs are merely ‘as good at’ humans at learning, but they can ‘merge brains’ then crazy things happen. How do we make such a situation go well? What is SSI’s plan?
   1. I mean, that’s the least of it, but hopefully yes that suffices to make the point?
2. Ilya emphasizes deploying incrementally and in advance. It’s hard to predict what this will be like in advance. “The problem is the power. When the power is really big, what’s going to happen? If it’s hard to imagine, what do you do? You’ve got to be showing the thing.”
   1. This feels like defeatism, in terms of saying we can only respond to things once we can see and appreciate them. We can’t plan for being old until we know what that’s like. We can’t plan for AGI/ASI, or AI having a lot of power, until we can see that in action.
   2. But obviously by then it is likely to be too late, and most of your ability to steer what happens has already been lost, perhaps all of it.
   3. This is the strategy of ‘muddle through’ the same as we always muddle through, basically the plan of not having a plan other than incrementalism. I do not care for this plan. I am not happy to be a part of it. I do not think that is a case of Safe Superintelligence.
3. Ilya expects governments and labs to play big roles, and for labs to increasingly coordinate on safety, as Anthropic and OpenAI did in a recent first step. And we have to figure out what we should be building. He suggests making the AI care about sentient life in general will be ‘easier’ than making it care about humans, since the AI will be sentient.
   1. If the AIs do not care about humans in particular, there is no reason to expect humans to stay in control or to long endure.
4. Ilya would like the most powerful superintelligence to ‘somehow’ be ‘capped’ to address these concerns. But he doesn’t know how to do that.
   1. I don’t know how to do that either. It’s not clear the idea is coherent.
5. Dwarkesh asks how much ‘room is there at the top’ for superintelligence to be more super? Maybe it just learns fast or has a bigger pool of strategies or skills or knowledge? Ilya says very powerful, for sure.
   1. Sigh. There is very obviously quite a lot of ‘room at the top’ and humans are not anything close to maximally intelligent, nor to getting most of what intelligence has to offer. At this point, the number of people who still don’t realize or accept this reinforces how much better a smarter entity could be.
6. Ilya expects these superintelligences to be very large, as in physically large, and for several to come into being at roughly the same time, and ideally they could “be restrained in some ways or if there was some kind of agreement or something.”
   1. That agreement between AIs would then be unlikely to include us. Yes, functional restraints would be nice, but this is the level of thought that has gone into finding ways to do it.
   2. There’s been a lot of things staying remarkably close, but a lot of that is because rather than an edge compounding and accelerating for now catching up has been easier.
7. Ilya: “What is the concern of superintelligence? What is one way to explain the concern? If you imagine a system that is sufficiently powerful, really sufficiently powerful—and you could say you need to do something sensible like care for sentient life in a very single-minded way—we might not like the results. That’s really what it is.”
   1. Well, yes, standard Yudkowsky, no fixed goal we can name turns out well.
8. Ilya says maybe we don’t build an RL agent. Humans are semi-RL agents, our emotions make us alter our rewards and pursue different rewards after a while. If we keep doing what we are doing now it will soon peter out and never be “it.”
   1. There’s a baked in level of finding innovations and improvements that should be in anyone’s ‘keep doing what we are doing’ prior, and I think it gets us pretty far and includes many individually low-probability-of-working innovations making substantial differences. There is some level on which we would ‘peter out’ without a surprise, but it’s not clear that this requires being surprised overall.
   2. Is it possible things do peter out and we never see ‘it’? Yeah. It’s possible. I think it’s a large underdog to stay that way for long, but it’s possible. Still a long practical way to go even then.
   3. Emotions, especially boredom and the fading of positive emotions on repetition, are indeed one of the ways we push ourselves towards exploration and variety. That’s one of many things they do, and yes if we didn’t have them then we would need something else to take their place.
   4. In many cases I have indeed used logic to take the place of that, when emotion seems to not be sufficiently preventing mode collapse.
9. “One of the things that you could say about what causes alignment to be difficult is that your ability to learn human values is fragile. Then your ability to optimize them is fragile. You actually learn to optimize them. And can’t you say, “Are these not all instances of unreliable generalization?” Why is it that human beings appear to generalize so much better? What if generalization was much better? What would happen in this case? What would be the effect? But those questions are right now still unanswerable.”
   1. It is cool to hear Ilya restate these Yudkowsky 101 things.
   2. Humans do not actually generalize all that well.
10. How does one think about what AI going well looks like? Ilya goes back to ‘AI that cares for sentient life’ as a first step, but then asks the better question, what is the long run equilibrium? He notices he does not like his answer. Maybe each person has an AI that will do their bidding and that’s good, but the downside is then the AI does things like earn money or advocate or whatever, and the person says ‘keep it up’ but they’re not a participant. Precarious. People become part AI, Neurolink++. He doesn’t like this solution, but it is at least a solution.
    1. Big points for acknowledging that there are no known great solutions.
    2. Big points for pointing out one big flaw, that the people stop actually doing the things, because the AIs do the things better.
    3. The equilibrium here is that increasingly more things are turned over to AIs, including both actions and decisions. Those who don’t do this fall behind.
    4. The equilibrium here is that increasingly AIs are given more autonomy, more control, put in better positions, have increasing power and wealth shares, and so on, even if everything involved is fully voluntary and ‘nothing goes wrong.’
    5. Neurolink++ does not meaningfully solve any of the problems here.
    6. Solve for the equilibrium.
11. Is the long history of emotions an alignment success? As in, it allows the brain to move from ‘mate with somebody who’s more successful’ into flexibly defining success and generally adjusting to new situations.
    1. It’s a highly mixed bag, wouldn’t you say?
    2. There are ways in which those emotions have been flexible and adaptable and a success, and have succeeded in the alignment target (inclusive genetic fitness) and also ways in which emotions are very obviously failing people.
    3. If ASIs are about as aligned as we are in this sense, we’re doomed.
12. Ilya says it’s mysterious how evolution encodes high-level desires, but it gives us all these social desires, and they evolved pretty recently. Dwarkesh points out it is desire you learned in your lifetime. Ilya notes the brain as regions and some things are hardcoded, but if you remove half the brain then the regions move, the social stuff is highly reliable.
    1. I don’t pretend to understand the details here, although I could speculate.

“We are squarely an age of research company”

1. SSI investigates ideas to see if they are promising. They do research.
2. On his cofounder leaving: “For this, I will simply remind a few facts that may have been forgotten. I think these facts which provide the context explain the situation. The context was that we were fundraising at a $32 billion valuation, and then Meta came in and offered to acquire us, and I said no. But my former cofounder in some sense said yes. As a result, he also was able to enjoy a lot of near-term liquidity, and he was the only person from SSI to join Meta.”
   1. I love the way he put that. Yes.
3. “The main thing that distinguishes SSI is its technical approach. We have a different technical approach that I think is worthy and we are pursuing it. I maintain that in the end there will be a convergence of strategies. I think there will be a convergence of strategies where at some point, as AI becomes more powerful, it’s going to become more or less clearer to everyone what the strategy should be. It should be something like, you need to find some way to talk to each other and you want your first actual real superintelligent AI to be aligned and somehow care for sentient life, care for people, democratic, one of those, some combination thereof. I think this is the condition that everyone should strive for. That’s what SSI is striving for. I think that this time, if not already, all the other companies will realize that they’re striving towards the same thing. We’ll see. I think that the world will truly change as AI becomes more powerful. I think things will be really different and people will be acting really differently.”
   1. This is a remarkably shallow, to me, vision of what the alignment part of the strategy looks like, but it does get an admirably large percentage of the overall strategic vision, as in most of it?
   2. The idea that ‘oh as we move farther along people will get more responsible and cooperate more’ seems to not match what we have observed so far, alas.
   3. Ilya later clarifies he specifically meant convergence on alignment strategies, although he also expects convergence on technical strategies.
   4. The above statement is convergence on an alignment goal, but that doesn’t imply convergence on alignment strategy. Indeed it does not imply that an alignment strategy that is workable even exists.
4. Ilya’s timeline to the system that can learn and become superhuman? 5-20 years.
5. Ilya predicts that when someone releases the thing that will be information but it won’t teach others how to do the thing, although they will eventually learn.
6. What is the ‘good world’? We have powerful human-like learners and perhaps narrow ASIs, and companies make money, and there is competition through specialization, different niches. Accumulated learning and investment creates specialization.
   1. This is so frustrating, in that it doesn’t explain why you would expect that to be how this plays out, or why this world turns out well, or anything really? Which would be fine if the answers were clear or at least those seemed likely, but I very much don’t think that.
   2. This feels like a claim that humans are indeed near the upper limit of what intelligence can do and what can be learned except that we are hobbled in various ways and AIs can be unhobbled, but that still leaves them functioning in ways that seem recognizably human and that don’t crowd us out? Except again I don’t think we should expect this.
7. Dwarkesh points out current LLMs are similar, Ilya says perhaps the datasets are not as non-overlapping as they seem.
   1. On the contrary, I was assuming they were mostly the same baseline data, and then they do different filtering and progressions from there? Not that there’s zero unique data but that most companies have ‘most of the data.’
8. Dwarkesh suggests, therefore AIs will have less diversity than human teams. How can we get ‘meaningful diversity’? Ilya says this is because of pretraining, that post training is different.
   1. To the extent that such ‘diversity’ is useful it seems easy to get with effort. I suspect this is mostly another way to create human copium.
9. What about using self-play? Ilya notes it allows using only compute, which is very interesting, but it is only good for ‘developing a certain set of skills.’ Negotiation, conflict, certain social strategies, strategizing, that kind of stuff. Then Ilya self-corrects, notes other forms, like debate, prover-verifier or forms of LLM-as-a-judge, it’s a special case of agent competition.
   1. I think there’s a lot of promising unexplored space here, decline to say more.

Research taste

1. What is research taste? How does Ilya come up with many big ideas?

This is hard to excerpt and seems important, so quoting in full to close out:

I can comment on this for myself. I think different people do it differently. One thing that guides me personally is an aesthetic of how AI should be, by thinking about how people are, but thinking correctly. It’s very easy to think about how people are incorrectly, but what does it mean to think about people correctly?

I’ll give you some examples. The idea of the artificial neuron is directly inspired by the brain, and it’s a great idea. Why? Because you say the brain has all these different organs, it has the folds, but the folds probably don’t matter. Why do we think that the neurons matter? Because there are many of them. It kind of feels right, so you want the neuron. You want some local learning rule that will change the connections between the neurons. It feels plausible that the brain does it.

The idea of the distributed representation. The idea that the brain responds to experience therefore our neural net should learn from experience. The brain learns from experience, the neural net should learn from experience. You kind of ask yourself, is something fundamental or not fundamental? How things should be.

I think that’s been guiding me a fair bit, thinking from multiple angles and looking for almost beauty, beauty and simplicity. Ugliness, there’s no room for ugliness. It’s beauty, simplicity, elegance, correct inspiration from the brain. All of those things need to be present at the same time. The more they are present, the more confident you can be in a top-down belief.

The top-down belief is the thing that sustains you when the experiments contradict you. Because if you trust the data all the time, well sometimes you can be doing the correct thing but there’s a bug. But you don’t know that there is a bug. How can you tell that there is a bug? How do you know if you should keep debugging or you conclude it’s the wrong direction? It’s the top-down. You can say things have to be this way. Something like this has to work, therefore we’ve got to keep going. That’s the top-down, and it’s based on this multifaceted beauty and inspiration by the brain.

I need to think more about what causes my version of ‘research taste.’ It’s definitely substantially different.

That ends our podcast coverage, and enter the bonus section, which seems better here than in the weekly, as it covers many of the same themes.

Bonus Coverage: Dwarkesh Patel on AI Progress These Days

Dwarkesh Patel offers his thoughts on AI progress these days, noticing that when we get the thing he calls ‘actual AGI’ things are going to get fucking crazy, but thinking that this is 10-20 years away from happening in full. Until then, he’s a bit skeptical of how many gains we can realize, but skepticism is highly relative here.

Dwarkesh Patel: I’m confused why some people have short timelines and at the same time are bullish on RLVR. If we’re actually close to a human-like learner, this whole approach is doomed.

… Either these models will soon learn on the job in a self directed way – making all this pre-baking pointless – or they won’t – which means AGI is not imminent. Humans don’t have to go through a special training phase where they need to rehearse every single piece of software they might ever use.

Wow, look at those goalposts move (in all the different directions). Dwarkesh notes that the bears keep shifting on the bulls, but says this is justified because current models fit the old goals but don’t score the points, as in they don’t automate workflows as much as you would expect.

In general, I worry about the expectation pattern having taken the form of ‘median 50 years → 20 → 10 → 5 → 7, and once I heard someone said 3, so oh nothing to see there you can stop worrying.’

In this case, look at the shift: An ‘actual’ (his term) AGI must now not only be capable of human-like performance of tasks, the AGI must also be a human-efficient learner.

That would mean AGI and ASI are the same thing, or at least arrive in rapid succession. An AI that was human-efficient at learning from data, combined with AI’s other advantages that include imbibing orders of magnitude more data, would be a superintelligence and would absolutely set off recursive self-improvement from there.

And yes, if that’s what you mean then AGI isn’t the best concept for thinking about timelines, and superintelligence is the better target to talk about. Sriram Krishnan is however opposed to using either of them.

Like all conceptual handles or fake frameworks, it is imprecise and overloaded, but people’s intuitions about it miss that the thing is possible or exists even when you outright say ‘superintelligence’ and I shudder to think how badly they will miss the concept if you don’t even say it. Which I think is a lot of the motivation behind not wanting to say it, so people can pretend that there won’t be things smarter than us in any meaningful sense and thus we can stop worrying about it or planning for it.

Indeed, this is exactly Sriram’s agenda if you look at his post here, to claim ‘we are not on the timeline’ that involves such things, to dismiss concerns as ‘sci-fi’ or philosophical, and talk instead of ‘what we are trying to build.’ What matters is what actually gets built, not what we intended, and no none of these concepts have been invalidated. We have ‘no proof of takeoff’ in the sense that we are not currently in a fast takeoff yet, but what would constitute this ‘proof’ other than already being in a takeoff, and thus it being too late to do anything about it?

Sriram Krishnan: …most importantly, it invokes fear—connected to historical usage in sci-fi and philosophy (think 2001, Her, anything invoking the singularity) that has nothing to do with the tech tree we’re actually on. Makes every AI discussion incredibly easy to anthropomorphize and detour into hypotheticals.

Joshua Achiam (OpenAI Head of Mission Alignment): I mostly disagree but I think this is a good contribution to the discourse. Where I disagree: I do think AGI and ASI both capture something real about where things are going. Where I agree: the lack of agreed-upon definitions has 100% created many needless challenges.

The idea that ‘hypotheticals,’ as in future capabilities and their logical consequences, are ‘detours,’ or that any such things are ‘sci-fi or philosophy’ is to deny the very idea of planning for future capabilities or thinking about the future in real ways. Sriram himself only thinks they are 10 years away, and then the difference is he doesn’t add Dwarkesh’s ‘and that’s fucking crazy’ and instead seems to effectively say ‘and that’s a problem for future people, ignore it.’

Seán Ó hÉigeartaigh: I keep noting this, but I do think a lot of the most heated policy debates we’re having are underpinned by a disagreement on scientific view: whether we (i) are on track in coming decade for something in the AGI/ASI space that can achieve scientific feats equivalent to discovering general relativity (Hassabis’ example), or (ii) should expect AI as a normal technology (Narayanan & Kapoor’s definition).

I honestly don’t know. But it feels premature to me to rule out (i) on the basis of (slightly) lengthening timelines from the believers, when progress is clearly continuing and a historically unprecedented level of resources are going into the pursuit of it. And premature to make policy on the strong expectation of (ii). (I also think it would be premature to make policy on the strong expectation of (i) ).

But we are coming into the time where policy centred around worldview (ii) will come into tension in various places with the policies worldview (i) advocates would enact if given a free hand. Over the coming decade I hope we can find a way to navigate a path between, rather than swing dramatically based on which worldview is in the ascendancy at a given time.

Sriram Krishnan: There is truth to this.

This paints it as two views, and I would say you need at least three:

1. Something in the AGI/ASI space is likely in less than 10 years.
2. Something in the AGI/ASI space is unlikely in less than about 10 years, but highly plausible in 10-20 years, until then AI is a normal technology.
3. AI is a normal technology and we know it will remain so indefinitely. We can regulate and plan as if AGI/ASI style technologies will never happen.

I think #1 and #2 are both highly reasonable positions, only #3 is unreasonable, while noting that if you believe #2 you still need to put some non-trivial weight on #1. As in, if you think it probably takes ~10 years then you can perhaps all but rule out AGI 2027, and you think 2031 is unlikely, but you cannot claim 2031 is a Can’t Happen.

The conflation to watch out for is #2 and #3. These are very different positions. Yet many in the AI industry, and its political advocates, make exactly this conflation. They assert ‘#1 is incorrect therefore #3,’ when challenged for details articulate claim #2, then go back to trying to claim #3 and act on the basis of #3.

What’s craziest is that the list of things to rule out, chosen by Sriram, includes the movie Her. Her made many very good predictions. Her was a key inspiration for ChatGPT and its voice mode, so much so that there was a threatened lawsuit because they all but copied Scarlett Johansson’s voice. She’s happening. Best be believing in sci-fi stores, because you’re living in one, and all that.

Nothing about current technology is a reason to think 2001-style things or a singularity will not happen, or to think we should anthropomorphize AI relatively less (the correct amount for current AIs, and for future AIs, are both importantly not zero, and importantly not 100%, and both mistakes are frequently made). Indeed, Dwarkesh is de facto predicting a takeoff and a singularity in this post that Sriram praised, except Dwarkesh has it on a 10-20 year timescale to get started.

Now, back to Dwarkesh.

This process of ‘teach the AI the specific tasks people most want’ is the central instance of models being what Teortaxes calls usemaxxed. A lot of effort is going to specific improvements rather than to advancing general intelligence. And yes, this is evidence against extremely short timelines. It is also, as Dwarkesh notes, evidence in favor of large amounts of mundane utility soon, including ability to accelerate R&D. What else would justify such massive ‘side’ efforts?

There’s also, as he notes, the efficiency argument. Skills many people want should be baked into the core model. Dwarkesh fires back that there are a lot of skills that are instance-specific and require on-the-job or continual learning, which he’s been emphasizing a lot for a while. I continue to not see a contradiction, or why it would be that hard to store and make available that knowledge as needed even if it’s hard for the LLM to permanently learn it.

I strongly disagree with his claim that ‘economic diffusion lag is cope for missing capabilities.’ I agree that many highly valuable capabilities are missing. Some of them are missing due to lack of proper scaffolding or diffusion or context, and are fundamentally Skill Issues by the humans. Others are foundational shortcomings. But the idea that the AIs aren’t up to vastly more tasks than they’re currently asked to do seems obviously wrong?

He quotes Steven Byrnes:

Steven Byrnes: New technologies take a long time to integrate into the economy? Well ask yourself: how do highly-skilled, experienced, and entrepreneurial immigrant humans manage to integrate into the economy immediately? Once you’ve answered that question, note that AGI will be able to do those things too.

Again, this is saying that AGI will be as strong as humans in the exact place it is currently weakest, and will not require adjustments for us to take advantage. No, it is saying more than that, it is also saying we won’t put various regulatory and legal and cultural barriers in its way, either, not in any way that counts.

If the AGI Dwarkesh is thinking about were to exist, again, it would be an ASI, and it would be all over for the humans very quickly.

I also strongly disagree with human labor not being ‘shleppy to train’ (bonus points, however, for excellent use of ‘shleppy’). I have trained humans and been a human being trained, and it is totally shleppy. I agree, not as schleppy as current AIs can be when something is out of their wheelhouse, but rather obnoxiously schleppy everywhere except their own very narrow wheelhouse.

Here’s another example of ‘oh my lord check out those goalposts’:

Dwarkesh Patel: It revealed a key crux between me and the people who expect transformative economic impacts in the next few years.

Transformative economic impacts in the next few years would be a hell of a thing.

It’s not net-productive to build a custom training pipeline to identify what macrophages look like given the way this particular lab prepares slides, then another for the next lab-specific micro-task, and so on. What you actually need is an AI that can learn from semantic feedback on the job and immediately generalize, the way a human does.

Well, no, it probably isn’t now, but also Claude Code is getting rather excellent at creating training pipelines, and the whole thing is rather standard in that sense, so I’m not convinced we are that far away from doing exactly that. This is an example of how sufficient ‘AI R&D’ automation, even on a small non-recursive scale, can transform use cases.

Every day, you have to do a hundred things that require judgment, situational awareness, and skills & context learned on the job. These tasks differ not just across different people, but from one day to the next even for the same person. It is not possible to automate even a single job by just baking in some predefined set of skills, let alone all the jobs.

Well, I mean of course it is, for a sufficiently broad set of skills at a sufficiently high level, especially if this includes meta-skills and you can access additional context. Why wouldn’t it be? It certainly can quickly automate large portions of many jobs, and yes I have started to automate portions of my job indirectly (as in Claude writes me the mostly non-AI tools to do it, and adjusts them every time they do something wrong).

Give it a few more years, though, and Dwarkesh is on the same page as I am:

In fact, I think people are really underestimating how big a deal actual AGI will be because they’re just imagining more of this current regime. They’re not thinking about billions of human-like intelligences on a server which can copy and merge all their learnings. And to be clear, I expect this (aka actual AGI) in the next decade or two. That’s fucking crazy!

Exactly. This ‘actual AGI’ is fucking crazy, and his timeline for getting there of 10-20 years is also fucking crazy. More people need to add ‘and that’s fucking crazy’ at the end of such statements.

Dwarkesh then talks more about continual learning. His position here hasn’t changed, and neither has my reaction that this isn’t needed, we can get the benefits other ways. He says that the gradual progress on continual learning means it won’t be ‘game set match’ to the first mover, but if this is the final piece of the puzzle then why wouldn’t it be?

2025-12-03 22:59:34

Published on December 3, 2025 2:59 PM GMT

Eliezer Yudkowsky has, on several occasions, claimed that AI’s success at protein folding was essentially predictable. His reasoning (e.g., here) is straightforward and convincing: proteins in our universe fold reliably; evolution has repeatedly found foldable and functional sequences; therefore the underlying energy landscapes must possess a kind of benign structure. If evolution can navigate these landscapes, then, with enough data and compute, machine learning should recover the mapping from amino-acid sequence to three-dimensional structure.

This account has rhetorical and inductive appeal. It treats evolution as evidence about the computational nature of protein folding and interprets AlphaFold as a natural consequence of biological priors. But the argument, as usually presented, fails to acknowledge what would be required for it to count as a formal heuristic. It presumes that evolutionary success necessitates the existence of a simple, learnable mapping. It presumes that the folding landscape is sufficiently smooth that the space of biologically relevant proteins is intrinsically easy. And it presumes that the success of a massive deep-learning model confirms that the problem was always secretly tractable.

These presumptions rely on an unspoken quantifier: for all proteins relevant to life, folding is easy. But this “for all” is not legitimate in a complexity-theoretic context unless the instance class has a precise and bounded description. Yudkowsky instead appeals to whatever evolution happened to discover. Evolution’s search process, however, is not a polytime algorithm but an unbounded historical trajectory with astronomical parallelism, billions of years of runtime, and immense filtering by selection pressures. Without explicit bounds, “evolution succeeded” does not imply anything about the inherent computational character of the underlying mapping. It merely establishes that a particular contingent subset of sequences—those the biosphere retained—happened to be foldable by natural dynamics.

If we shift to formal models, the general protein-folding problem remains NP-hard under standard abstraction schemes. That does not mean biological folding is NP-hard, only that no claim about the general tractability of the sequence to structure mapping can be inferred from evolutionary success. What matters for tractability is not the full space of possible proteins but the restricted subset that life explores. Yudkowsky’s argument, by treating evolutionary selection as direct evidence of easy energy landscapes, smuggles in the structural properties of that restricted set without acknowledging that these properties are exactly what must be demonstrated, not simply asserted.

The computational picture looks very different. The biosphere does not sample uniformly from all possible sequences. Instead, it occupies a tiny, closed, highly structured subset of sequence space—an extraordinarily low-Kolmogorov-complexity region characterized by a few thousand fold families, extensive modularity, and strong physical constraints on designability. This subset bears almost no resemblance to the adversarial or worst-case instances that drive NP-hardness proofs. With a bit hand-waving,^[1]

$\begin{array}{ccc}{B}_n& \ll & {\Sigma }^n,\\ \mathrm{KC}\left(B_n\right)& \ll & \mathrm{KC}\left({\Sigma }^n\right),\\ \mathrm{Struct}\left(B_n\right)& ⋐& {\mathrm{Struct}}_{adv},\\ F{|}_{B_n}& \in & P/poly\text{but}F\notin P/poly.\end{array}$

Once attention is confined to that biologically realized region, the folding map ceases to be the general NP-hard problem and becomes a promise problem over a heavily compressed instance class. The problem is not hard, it's just big.

Seen this way, the achievement of AlphaFold is not evidence that “protein folding was always solvable,” but evidence that modern machine learning can use enormous non-uniform information—training data, evolutionary alignments, known structures—to approximate a mapping defined over a small and highly regularized domain. The training process acts as a vast preprocessing step, analogous to non-uniform advice in complexity theory. The final trained model is essentially a polytime function augmented by a massive advice string (its learned parameters), specialized to a single distribution. Evolution itself plays a similar role: after billions of years of search, it has curated only those sequences that belong to a region of the landscape where folding is stable, kinetically accessible, and robust to perturbation. The process is not evidence that folding is uniformly simple; it is evidence that evolution found a tractable island inside an intractable ocean.

This distinction matters because it reframes the “predictability” of AlphaFold’s success. Yudkowsky presents folding as solvable because biological energy landscapes are smooth enough to make evolution effective. But smoothness on the evolutionary subset does not entail smoothness on the entire space; nor does it imply that this subset is algorithmically accessible without vast volumes of preprocessing. A complexity-theoretic interpretation views the success of deep learning not as the discovery of a simple universal rule but as the extraction of structure from a domain that has already been heavily pruned, compressed, and optimized by natural history. The learning system inherits its tractability from the fact that the problem has been pre-worked into a low-entropy form.

There is therefore a straightforward computational reason why the “evolution shows folding is easy” argument does not succeed as an explanation: it conflates a historical process without resource bounds with an algorithmic claim that requires them. It interprets the existence of foldable proteins as proof of benign complexity rather than as the output of a long, unbounded filtration that carved out a tractable subclass. The right explanatory frame is not “energy landscapes are nice,” but “biology inhabits a closed problem class with small descriptive complexity, and our algorithms exploit vast non-uniform information about that class.”

Yudkowsky’s argument gestures toward the right conclusion—that solvability was unsurprising—but gives the wrong reason. The crucial structure lies not in universal physics but in the finite, closed domain evolution left to us, and in the immense preprocessing our models perform before they ever encounter a new sequence. The success of AlphaFold was predictable only conditional on the recognition that the real problem is not worst-case folding but folding within a compact distribution carved out by evolutionary history and indexed in publicly available data. What makes the achievement unsurprising is not that physical energy landscapes are globally smooth, but that the domain evolution generated is sufficiently structured, and sufficiently well-sampled, to permit high-fidelity interpolation.

In essence, no one has solved the actual problem, because any solver specialized to the evolutionary subset is guaranteed to fail once the promise is removed; outside that tightly curated domain, the mapping reverts to an unbounded and intractable instance class.

(Context: much contemporary discourse treats machine learning as if it were solving an analytic problem over a vast, effectively unbounded function space—an optimization in a continuous “classic” domain, governed by gradient dynamics and statistical generalization. But what learning systems actually deliver, when examined through a computational or logical lens, is a highly non-uniform procedure specialized to a sharply delimited region of instance space. The argument above says: computation is always local, effective behavior emerges once the space is sufficiently structured, compressed, or bounded by a promise. It follows from “constructive logic,” computational statements should be made relative to well-defined objects, not idealized totalities.)

1. ^{^}

   $B_n$, biologically realized sequences of length (n);  ${\Sigma }^n$, sequences
   $\mathrm{KC}(\cdot )$ Kolmogorov complexity; $\mathrm{Struct}\left(B_n\right)$, reductions realized by $B_n$; adv, adversarial or worst-case structures; $F{|}_{B_n}$, folding restricted to biological instances; $P/poly$, non-uniform polynomial time.