This is the final discussion log in the Late 2021 MIRI Conversations sequence, featuring Rohin Shah and Eliezer Yudkowsky, with additional comments from Rob Bensinger, Nate Soares, Richard Ngo, and Jaan Tallinn.
The discussion begins with summaries and comments on Richard and Eliezer's debate. Rohin's summary has since been revised and published in the Alignment Newsletter.
After this log, we'll be concluding this sequence with an AMA, where we invite you to comment with questions about AI alignment, cognition, forecasting, etc. Eliezer, Richard, Paul Christiano, Nate, and Rohin will all be participating.
|Chat by Rohin and Eliezer||Other chat||Emails||Follow-ups|
19. Follow-ups to the Ngo/Yudkowsky conversation
19.1. Quotes from the public discussion
[Bensinger][9:22] (Nov. 25)
Interesting extracts from the public discussion of Ngo and Yudkowsky on AI capability gains:
19.2. Rohin Shah's summary and thoughts
[Shah][7:06] (Nov. 6 email)
Newsletter summaries attached, would appreciate it if Eliezer and Richard checked that I wasn't misrepresenting them. (Conversation is a lot harder to accurately summarize than blog posts or papers.)
Planned summary for the Alignment Newsletter:
Eliezer is known for being pessimistic about our chances of averting AI catastrophe. His main argument is roughly as follows:
[Yudkowsky][9:56] (Nov. 6 email reply)
I request that people stop describing things as my "main argument" unless I've described them that way myself. These are answers that I customized for Richard Ngo's questions. Different questions would get differently emphasized replies. "His argument in the dialogue with Richard Ngo" would be fine.
[Shah][1:53] (Nov. 8 email reply)
Fair enough. It still does seem pretty relevant to know the purpose of the argument, and I would like to state something along those lines in the summary. For example, perhaps it is:
If you can't really say, then I guess I'll just say "His argument in this particular dialogue".
I'd also like to know what the main argument is (if there is a main argument rather than lots of independent lines of evidence or something else entirely); it helps me orient to the discussion, and I suspect would be useful for newsletter readers as well.
[Shah][7:06] (Nov. 6 email)
1. We are very likely going to keep improving AI capabilities until we reach AGI, at which point either the world is destroyed, or we use the AI system to take some pivotal act before some careless actor destroys the world.
2. In either case, the AI system must be producing high-impact, world-rewriting plans; such plans are “consequentialist” in that the simplest way to get them (and thus, the one we will first build) is if you are forecasting what might happen, thinking about the expected consequences, considering possible obstacles, searching for routes around the obstacles, etc. If you don’t do this sort of reasoning, your plan goes off the rails very quickly; it is highly unlikely to lead to high impact. In particular, long lists of shallow heuristics (as with current deep learning systems) are unlikely to be enough to produce high-impact plans.
3. We’re producing AI systems by selecting for systems that can do impressive stuff, which will eventually produce AI systems that can accomplish high-impact plans using a general underlying “consequentialist”-style reasoning process (because that’s the only way to keep doing more impressive stuff). However, this selection process does not constrain the goals towards which those plans are aimed. In addition, most goals seem to have convergent instrumental subgoals like survival and power-seeking that would lead to extinction. This suggests that, unless we find a way to constrain the goals towards which plans are aimed, we should expect an existential catastrophe.
4. None of the methods people have suggested for avoiding this outcome seem like they actually avert this story.
[Yudkowsky][9:56] (Nov. 6 email reply)
I would not say we face catastrophe "unless we find a way to constrain the goals towards which plans are aimed". This is, first of all, not my ontology, second, I don't go around randomly slicing away huge sections of the solution space. Workable: "This suggests that we should expect an existential catastrophe by default."
[Shah][1:53] (Nov. 8 email reply)
Should I also change "However, this selection process does not constrain the goals towards which those plans are aimed", and if so what to? (Something along these lines seems crucial to the argument, but if this isn't your native ontology, then presumably you have some other thing you'd say here.)
[Shah][7:06] (Nov. 6 email)
Richard responds to this with a few distinct points:
1. It might be possible to build narrow AI systems that humans use to save the world, for example, by making AI systems that do better alignment research. Such AI systems do not seem to require the property of making long-term plans in the real world in point (3) above, and so could plausibly be safe. We might say that narrow AI systems could save the world but can’t destroy it, because humans will put plans into action for the former but not the latter.
2. It might be possible to build general AI systems that only state plans for achieving a goal of interest that we specify, without executing that plan.
3. It seems possible to create consequentialist systems with constraints upon their reasoning that lead to reduced risk.
4. It also seems possible to create systems that make effective plans, but towards ends that are not about outcomes in the real world, but instead are about properties of the plans -- think for example of corrigibility (AN #35) or deference to a human user.
5. (Richard is also more bullish on coordinating not to use powerful and/or risky AI systems, though the debate did not discuss this much.)
1. This is plausible, but seems unlikely; narrow not-very-consequentialist AI (aka “long lists of shallow heuristics”) will probably not scale to the point of doing alignment research better than humans.
[Yudkowsky][9:56] (Nov. 6 email reply)
No, your summarized-Richard-1 is just not plausible. "AI systems that do better alignment research" are dangerous in virtue of the lethally powerful work they are doing, not because of some particular narrow way of doing that work. If you can do it by gradient descent then that means gradient descent got to the point of doing lethally dangerous work. Asking for safely weak systems that do world-savingly strong tasks is almost everywhere a case of asking for nonwet water, and asking for AI that does alignment research is an extreme case in point.
[Shah][1:53] (Nov. 8 email reply)
How about "AI systems that help with alignment research to a sufficient degree that it actually makes a difference are almost certainly already dangerous."?
(Fwiw, I used the word "plausible" because of this sentence from the doc: "Definitely, <description of summarized-Richard-1> is among the more plausible advance-specified miracles we could get.", though I guess the point was that it is still a miracle, it just also is more likely than other miracles.)
[Ngo][9:59] (Nov. 6 email reply)
Thanks Rohin! Your efforts are much appreciated.
Eliezer: when you say "No, your summarized-Richard-1 is just not plausible", do you mean the argument is implausible, or it's not a good summary of my position (which you also think is implausible)?
For my part the main thing I'd like to modify is the term "narrow AI". In general I'm talking about all systems that are not of literally world-destroying intelligence+agency. E.g. including oracle AGIs which I wouldn't call "narrow".
More generally, I don't think all AGIs are capable of destroying the world. E.g. humans are GIs. So it might be better to characterise Eliezer as talking about some level of general intelligence which leads to destruction, and me as talking about the things that can be done with systems that are less general or less agentic than that.
I don't endorse this, I think plenty of humans would be willing to use narrow AI systems to do things that could destroy the world.
I'd change this to say "systems with the primary aim of producing plans with certain properties (that aren't just about outcomes in the world)"
[Yudkowsky][10:18] (Nov. 6 email reply)
I wouldn't have presumed to state on your behalf whether it's a good summary of your position! I mean that the stated position is implausible, whether or not it was a good summary of your position.
[Shah][7:06] (Nov. 6 email)
2. This might be an improvement, but not a big one. It is the plan itself that is risky; if the AI system made a plan for a goal that wasn’t the one we actually meant, and we don’t understand that plan, that plan can still cause extinction. It is the misaligned optimization that produced the plan that is dangerous, even if there was no “agent” that specifically wanted the goal that the plan was optimized for.
3 and 4. It is certainly possible to do such things; the space of minds that could be designed is very large. However, it is difficult to do such things, as they tend to make consequentialist reasoning weaker, and on our current trajectory the first AGI that we build will probably not look like that.
[Yudkowsky][9:56] (Nov. 6 email reply)
No, it's not a significant improvement if the "non-executed plans" from the system are meant to do things in human hands powerful enough to save the world. They could of course be so weak as to make their human execution have no inhumanly big consequences, but this is just making the AI strategically isomorphic to a rock. The notion of there being "no 'agent' that specifically wanted the goal" seems confused to me as well; this is not something I'd ever say as a restatement of one of my own opinions. I'd shrug and tell someone to taboo the word 'agent' and would try to talk without using the word if they'd gotten hung up on that point.
[Shah][7:06] (Nov. 6 email)
I first want to note my violent agreement with the notion that a major scary thing is “consequentialist reasoning”, and that high-impact plans require such reasoning, and that we will end up building AI systems that produce high-impact plans. Nonetheless, I am still optimistic about AI safety relative to Eliezer, which I suspect comes down to three main disagreements:
1. There are many approaches that don’t solve the problem, but do increase the level of intelligence required before the problem leads to extinction. Examples include Richard’s points 1-4 above. For example, if we build a system that states plans without executing them, then for the plans to cause extinction they need to be complicated enough that the humans executing those plans don’t realize that they are leading to an outcome that was not what they wanted. It seems non-trivially probable to me that such approaches are sufficient to prevent extinction up to the level of AI intelligence needed before we can execute a pivotal act.
2. The consequentialist reasoning is only scary to the extent that it is “aimed” at a bad goal. It seems non-trivially probable to me that it will be “aimed” at a goal sufficiently good to not lead to existential catastrophe, without putting in much alignment effort.
I wish the debate had focused more on the claim that narrow AI can’t e.g. do better alignment research, as it seems like a major crux. (For example, I think that sort of intuition drives my disagreement #1.) I expect AI progress looks a lot like “the heuristics get less and less shallow in a gradual / smooth / continuous manner” which eventually leads to the sorts of plans Eliezer calls “consequentialist”, whereas I think Eliezer expects a sharper qualitative change between “lots of heuristics” and that-which-implements-consequentialist-planning.
20. November 6 conversation
20.1. Concrete plans, and AI-mediated transparency
So I have a general thesis about a failure mode here which is that, the moment you try to sketch any concrete plan or events which correspond to the abstract descriptions, it is much more obviously wrong, and that is why the descriptions stay so abstract in the mouths of everybody who sounds more optimistic than I am.
This may, perhaps, be confounded by the phenomenon where I am one of the last living descendants of the lineage that ever knew how to say anything concrete at all. Richard Feynman - or so I would now say in retrospect - is noticing concreteness dying out of the world, and being worried about that, at the point where he goes to a college and hears a professor talking about "essential objects" in class, and Feynman asks "Is a brick an essential object?" - meaning to work up to the notion of the inside of a brick, which can't be observed because breaking a brick in half just gives you two new exterior surfaces - and everybody in the classroom has a different notion of what it would mean for a brick to be an essential object.
Richard Feynman knew to try plugging in bricks as a special case, but the people in the classroom didn't, and I think the mental motion has died out of the world even further since Feynman wrote about it. The loss has spread to STEM as well. Though if you don't read old books and papers and contrast them to new books and papers, you wouldn't see it, and maybe most of the people who'll eventually read this will have no idea what I'm talking about because they've never seen it any other way...
I have a thesis about how optimism over AGI works. It goes like this: People use really abstract descriptions and never imagine anything sufficiently concrete, and this lets the abstract properties waver around ambiguously and inconsistently to give the desired final conclusions of the argument. So MIRI is the only voice that gives concrete examples and also by far the most pessimistic voice; if you go around fully specifying things, you can see that what gives you a good property in one place gives you a bad property someplace else, you see that you can't get all the properties you want simultaneously. Talk about a superintelligence building nanomachinery, talk concretely about megabytes of instructions going to small manipulators that repeat to lay trillions of atoms in place, and this shows you a lot of useful visible power paired with such unpleasantly visible properties as "no human could possibly check what all those instructions were supposed to do".
Abstract descriptions, on the other hand, can waver as much as they need to between what's desirable in one dimension and undesirable in another. Talk about "an AGI that just helps humans instead of replacing them" and never say exactly what this AGI is supposed to do, and this can be so much more optimistic so long as it never becomes too unfortunately concrete.
When somebody asks you "how powerful is it?" you can momentarily imagine - without writing it down - that the AGI is helping people by giving them the full recipes for protein factories that build second-stage nanotech and the instructions to feed those factories, and reply, "Oh, super powerful! More than powerful enough to flip the gameboard!" Then when somebody asks how safe it is, you can momentarily imagine that it's just giving a human mathematician a hint about proving a theorem, and say, "Oh, super duper safe, for sure, it's just helping people!"
Or maybe you don't even go through the stage of momentarily imagining the nanotech and the hint, maybe you just navigate straight in the realm of abstractions from the impossibly vague wordage of "just help humans" to the reassuring and also extremely vague "help them lots, super powerful, very safe tho".
It is in this spirit that I now ask, "What the hell could it look like concretely for a safely narrow AI to help with alignment research?"
Or if you think that a left-handed wibble planner can totally make useful plans that are very safe because it's all leftish and wibbly: can you please give an example of a plan to do what?
And what I expect is for minds to bounce off that problem as they first try to visualize "Well, a plan to give mathematicians hints for proving theorems... oh, Eliezer will just say that's not useful enough to flip the gameboard... well, plans for building nanotech... Eliezer will just say that's not safe... darn it, this whole concreteness thing is such a conversational no-win scenario, maybe there's something abstract I can say instead".
It's reasonable to suspect failures to be concrete, but I don't buy that hypothesis as applied to me; I think I have sufficient personal evidence against it, despite the fact that I usually speak abstractly. I don't expect to convince you of this, nor do I particularly want to get into that sort of debate.
I'll note that I have the exact same experience of not seeing much concreteness, both of other people and myself, about stories that lead to doom. To be clear, in what I take to be the Eliezer-story, the part where the misaligned AI designs a pathogen that wipes out all humans or solves nanotech and gains tons of power or some other pivotal act seems fine. The part that seems to lack concreteness is how we built the superintelligence and why the superintelligence was misaligned enough to lead to extinction. (Well, perhaps. I also wouldn't be surprised if you gave a concrete example and I disagreed that it would lead to extinction.)
From my perspective, the simple concrete stories about the future are wrong and the complicated concrete stories about the future don't sound plausible, whether about safety or about doom.
Nonetheless, here's an attempt at some concrete stories. It is not the case that I think these would be convincing to you. I do expect you to say that it won't be useful enough to flip the gameboard (or perhaps that if it could possibly flip the gameboard then it couldn't be safe), but that seems to be because you think alignment will be way more difficult than I do (in expectation), and perhaps we should get into that instead.
(These are all basically leveraging the fact that we could have AI systems that are really knowledgeable in the realm of "connecting neural net activations to human concepts", which seems plausible to do without being super general or consequentialist.)
There's also lots of meta stuff, like helping us with literature reviews, speeding up paper- and blog-post-writing, etc, but I doubt this is getting at what you care about
If we thought that helping with literature review was enough to save the world from extinction, then we should be trying to spend at least $50M on helping with literature review right now today, and if we can't effectively spend $50M on that, then we also can't build the dataset required to train narrow AI to do literature review. Indeed, any time somebody suggests doing something weak with AGI, my response is often "Oh how about we start on that right now using humans, then," by which question its pointlessness is revealed.
I mean, doesn't seem crazy to just spend $50M on effective PAs, but in any case I agree with you that this is not the main thing to be thinking about
The other cases of "using narrow AI to help with alignment" via pointing an AI, or rather a loss function, at a transparency problem, seem to seamlessly blend into all of the other clever-ideas we may have for getting more insight into the giant inscrutable matrices of floating-point numbers. By this concreteness, it is revealed that we are not speaking of von-Neumann-plus-level AGIs who come over and firmly but gently set aside our paradigm of giant inscrutable matrices, and do something more alignable and transparent; rather, we are trying more tricks with loss functions to get human-language translations of the giant inscrutable matrices.
I have thought of various possibilities along these lines myself. They're on my list of things to try out when and if the EA community has the capacity to try out ML ideas in a format I could and would voluntarily access.
There's a basic reason I expect the world to die despite my being able to generate infinite clever-ideas for ML transparency, which, at the usual rate of 5% of ideas working, could get us as many as three working ideas in the impossible event that the facilities were available to test 60 of my ideas.
Agreed, but I don't see the point here
(Beyond "Rohin and Eliezer disagree on how impossible it is to align giant inscrutable matrices")
(I might dispute "tricks with loss functions", but that's nitpicky, I think)
It's that, if we get better transparency, we are then left looking at stronger evidence that our systems are planning to kill us, but this will not help us because we will not have anything we can do to make the system not plan to kill us.
The adversarial training case is one example where you are trying to change the system, and if you'd like I can generate more along these lines, but they aren't going to be that different and are still going to come down to what I expect you will call "playing tricks with loss functions"
Well, part of the point is that "AIs helping us with alignment" is, from my perspective, a classic case of something that might ambiguate between the version that concretely corresponds to "they are very smart and can give us the Textbook From The Future that we can use to easily build a robust superintelligence" (which is powerful, pivotal, unsafe, and kills you) or "they can help us with literature review" (safe, weak, unpivotal) or "we're going to try clever tricks with gradient descent and loss functions and labeled datasets to get alleged natural-language translations of some of the giant inscrutable matrices" (which was always the plan but which I expected to not be sufficient to avert ruin).
I'm definitely thinking of the last one, but I take your point that disambiguating between these is good
And I also think it's revealing that this is not in fact the crux of disagreement
20.2. Concrete disaster scenarios, out-of-distribution problems, and corrigibility
I have a boundless supply of greater concrete detail for the asking, though if you ask large questions I may ask for a narrower question to avoid needing to supply 10,000 words of concrete detail.
I guess the main thing is to have an example of a story which includes a method for building a superintelligence (yes, I realize this is info-hazard-y, sorry, an abstract version might work) + how it becomes misaligned and what its plans become optimized for. Though as I type this out I realize that I'm likely going to disagree on the feasibility of the method for building a superintelligence?
I mean, I'm obviously not going to want to make any suggestions that I think could possibly work and which are not very very very obvious.
Yup, makes sense
But I don't think that's much of an issue.
I could just point to MuZero, say, and say, "Suppose something a lot like this scaled."
Do I need to explain how you would die in this case?
What sort of domain and what training data?
Like, do we release a robot in the real world, have it collect data, build a world model, and run MuZero with a reward for making a number in a bank account go up?
Supposing they're naive about it: playing all the videogames, predicting all the text and images, solving randomly generated computer puzzles, accomplishing sets of easily-labelable sensorymotor tasks using robots and webcams
Okay, so far I'm with you. Is there a separate deployment step, and if so, how did they finetune the agent for the deployment task? Or did it just take over the world halfway through training?
(though this starts to depart from the Mu Zero architecture if it has the ability to absorb knowledge via learning on more purely predictive problems)
(I'm okay with that, I think)
vaguely plausible rough scenario: there was a big ongoing debate about whether or not to try letting the system trade stocks, and while the debate was going on, the researchers kept figuring out ways to make Something Zero do more with less computing power, and then it started visibly talking at people and trying to manipulate them, and there was an enormous fuss, and what happens past this point depends on whether or not you want me to try to describe a scenario in which we die with an unrealistic amount of dignity, or a realistic scenario where we die much faster
I shall assume the former.
Actually I think I want concreteness earlier
Okay. I await your further query.
What caused this?
Was it manipulating people in order to make e.g. sensory stuff easier to predict?
Cumulative lifelong learning from playing videogames took its planning abilities over a threshold; cumulative solving of computer games and multimodal real-world tasks took its internal mechanisms for unifying knowledge and making them coherent over a threshold; and it gained sufficient compressive understanding of the data it had implicitly learned by reading through hundreds of terabytes of Common Crawl, not so much the semantic knowledge contained in those pages, but the associated implicit knowledge of the Things That Generate Text (aka humans).
These combined to form an imaginative understanding that some of its real-world problems were occurring in interactions with the Things That Generate Text, and it started making plans which took that into account and tried to have effects on the Things That Generate Text in order to affect the further processes of its problems.
Or perhaps somebody trained it to write code in partnership with programmers and it already had experience coworking with and manipulating humans.
Checking understanding: At this point it is able to make novel plans that involve applying knowledge about humans and their role in the data-generating process in order to create a plan that leads to more reward for the real-world problems?
(Which we call "manipulating humans")
Yes, much as it might have gained earlier experience with making novel Starcraft plans that involved "applying knowledge about humans and their role in the data-generating process in order to create a plan that leads to more reward", if it was trained on playing Starcraft against humans at any point, or even needed to make sense of how other agents had played Starcraft
This in turn can be seen as a direct outgrowth and isomorphism of making novel plans for playing Super Mario Brothers which involve understanding Goombas and their role in the screen-generating process
except obviously that the Goombas are much less complicated and not themselves agents
Yup, makes sense. Not sure I totally agree that this sort of thing is likely to happen as quickly as it sounds like you believe but I'm happy to roll with it; I do think it will happen eventually
So doesn't seem particularly cruxy
I can see how this leads to existential catastrophe, if you don't expect the programmers to be worried at this early manipulation warning sign. (This is potentially cruxy for p(doom), but doesn't feel like the main action.)
On my mainline, where this is all happening at Deepmind, I do expect at least one person in the company has ever read anything I've written. I am not sure if Demis understands he is looking straight at death, but I am willing to suppose for the sake of discussion that he does understand this - which isn't ruled out by my actual knowledge - and talk about how we all die from there.
The very brief tl;dr is that they know they're looking at a warning sign but they cannot
I assume this is primarily about social dynamics + the ability to patch things such that things look fixed?
Yeah, makes sense
I assume the "real underlying problem" is somehow not the fact that the task you were training your AI system to do was not what you actually wanted it to do?
It's about the unavailability of any actual fix and the technology continuing to get easier. Even if Deepmind understands that surface patches are lethal and understands that the easy ways of hammering down the warning signs are just eliminating the visibility rather than the underlying problems, there is nothing they can do about that except wait for somebody else to destroy the world instead.
I do not know of any pivotal task you could possibly train an AI system to do using tons of correctly labeled data. This is part of why we're all dead.
Yeah, I think if I adopted (my understanding of) your beliefs about alignment difficulty, and there wasn't already a non-racing scheme set in place, seems like we're in trouble
Like, "the real underlying problem is the fact that the task you were training your AI system to do was not what you actually wanted it to do" is one way of looking at one of the several problems that are truly fundamental, but this has no remedy that I know of, besides training your AI to do something small enough to be unpivotal.
I don't actually know the response you'd have to "why not just do value alignment?" I can name several guesses
To be concrete, you can't ask the AGI to build one billion nanosystems, label all the samples that wiped out humanity as bad, and apply gradient descent updates
|In part, you can't do that because one billion samples will get you one billion lethal systems, but even if that wasn't true, you still couldn't do it.|
Why not? Nearest unblocked strategy?
...no, because the first supposed output for training generated by the system at superintelligent levels kills everyone and there is nobody left to label the data.
Oh, I thought you were asking me to imagine away that effect with your second sentence
In fact, I still don't understand what it was supposed to mean
(Specifically this one:
there's a separate problem where you can't apply reinforcement learning when there's no good examples, even assuming you live to label them
and, of course, yet another form of problem where you can't tell the difference between good and bad samples
Okay, makes sense
Let me think a bit
and lest anyone start thinking that was an exhaustive list of fundamental problems, note the absence of, for example, "applying lots of optimization using an outer loss function doesn't necessarily get you something with a faithful internal cognitive representation of that loss function" aka "natural selection applied a ton of optimization power to humans using a very strict very simple criterion of 'inclusive genetic fitness' and got out things with no explicit representation of or desire towards 'inclusive genetic fitness' because that's what happens when you hill-climb and take wins in the order a simple search process through cognitive engines encounters those wins"
(Agreed that is another major fundamental problem, in the sense of something that could go wrong, as opposed to something that almost certainly goes wrong)
I am still curious about the "why not value alignment" question, where to expand, it's something like "let's get a wide range of situations and train the agent with gradient descent to do what a human would say is the right thing to do". (We might also call this "imitation"; maybe "value alignment" isn't the right term, I was thinking of it as trying to align the planning with "human values".)
My own answer is that we shouldn't expect this to generalize to nanosystems, but that's again much more of a "there's not great reason to expect this to go right, but also not great reason to go wrong either".
(This is a place where I would be particularly interested in concreteness, i.e. what does the AI system do in these cases, and how does that almost-necessarily follow from the way it was trained?)
what's an example element from the "wide range of situations" and what is the human labeling?
(I could make something up and let you object, but it seems maybe faster to ask you to make something up)
Uh, let's say that the AI system is being trained to act well on the Internet, and it's shown some tweet / email / message that a user might have seen, and asked to reply to the tweet / email / message. User says whether the replies are good or not (perhaps via comparisons, a la Deep RL from Human Preferences)
If I were not making it up on the spot, it would be more varied than that, but would not include "building nanosystems"
And presumably, in this example, the AI system is not smart enough that exposing humans to text it generates is already a world-wrecking threat if the AI is hostile?
i.e., does not just hack the humans
Yeah, let's assume that for the moment
so what you want to do is train on 'weak-safe' domains where the AI isn't smart enough to do damage, and the humans can label the data pretty well because the AI isn't smart enough to fool them
"want to do" is putting it a bit strongly. This is more like a scenario I can't prove is unsafe, but do not strongly believe is safe
but the domains where the AI can execute a world-saving pivotal act are out-of-distribution for those domains. extremely out-of-distribution. fundamentally out-of-distribution. the AI's own thought processes are out-of-distribution for any inscrutable matrices that were learned to influence those thought processes in a corrigible direction.
it's not like trying to generalize experience from playing Super Mario Bros to Metroid.
Definitely, but my reaction to this is "okay, no particular reason for it to be safe" -- but also not huge reason for it to be unsafe. Like, it would not hugely shock me if what-we-want is sufficiently "natural" that the AI system picks up on the right thing form the 'weak-safe' domains alone
you have this whole big collection of possible AI-domain tuples that are powerful-dangerous and they have properties that aren't in any of the weak-safe training situations, that are moving along third dimensions where all the weak-safe training examples were flat
now, just because something is out-of-distribution, doesn't mean that nothing can ever generalize there
I mean, you correctly would not accept this argument if I said that by training blue-car-driving robots solely on blue cars I am ensuring they would be bad on red-car-driving
humans generalize from the savannah to the vacuum
so the actual problem is that I expect the optimization to generalize and the corrigibility to fail
I am not clear on why you expect this so strongly
Maybe you think generalization is extremely rare and optimization is a special case because of how it is so useful for basically everything?
did you read the section of my dialogue with Richard Ngo where I tried to explain why corrigibility is anti-natural, or where Nate tried to give the example of why planning to get a laser from point A to point B without being scattered by fog is the sort of thing that also naturally says to prevent humans from filling the room with fog?
Ah, right, I should have predicted that. (Yes, I did read it.)
or for that matter, am I correct in remembering that these sections existed
so, do you need more concrete details about some part of that?
a bunch of the reason why I suspect that corrigibility is anti-natural is from trying to work particular problems there in MIRI's earlier history, and not finding anything that wasn't contrary to
I think I disagreed with that part more directly, in that it seemed like in those sections the corrigibility was assumed to be imposed "from the outside" on top of a system with a goal, rather than having a goal that was corrigible. (I also had a similar reaction to the 2015 Corrigibility paper.)
So, for example, it seems to me like CIRL is an example of an objective that can be maximized in which the agent is corrigible-in-a-certain-sense. I agree that due to updated deference it will eventually stop seeking information from the human / be subject to corrections by the human. I don't see why, at that point, it wouldn't have just learned to do what the humans actually want it to do.
(There are objections like misspecification of the reward prior, or misspecification of the P(behavior | reward), but those feel like different concerns to the ones you're describing.)
a thing that MIRI tried and failed to do was find a sensible generalization of expected utility which could contain a generalized utility function that would look like an AI that let itself be shut down, without trying to force you to shut it down
and various workshop attendees not employed by MIRI, etc
I do agree that a CIRL agent would not let you shut it down
And this is something that should maybe give you pause, and be a lot more careful about potential misspecification problems
if you could give a perfectly specified prior such that the result of updating on lots of observations would be a representation of the utility function that CEV outputs, and you could perfectly inner-align an optimizer to do that thing in a way that scaled to arbitrary levels of cognitive power, then you'd be home free, sure.
I'm not trying to claim this is a solution. I'm more trying to point at a reason why I am not convinced that corrigibility is anti-natural.
the reason CIRL doesn't get off the ground is that there isn't any known, and isn't going to be any known, prior over (observation|'true' utility function) such that an AI which updates on lots of observations ends up with our true desired utility function.
if you can do that, the AI doesn't need to be corrigible
that's why it's not a counterexample to corrigibility being anti-natural
the AI just boomfs to superintelligence, observes all the things, and does all the goodness
it doesn't listen to you say no and won't let you shut it down, but by hypothesis this is fine because it got the true utility function yay
In the world where it doesn't immediately start out as a superintelligence, it spends a lot of time trying to figure out what you want, asking you what you prefer it does, making sure to focus on the highest-EV questions, being very careful around any irreversible actions, etc
and making itself smarter as fast as possible
Yup, that too
I'd do that stuff too if I was waking up in an alien world
and, with all due respect to myself, I am not corrigible
You'd do that stuff because you'd want to make sure you don't accidentally get killed by the aliens; a CIRL agent does it because it "wants to help the human"
no, a CIRL agent does it because it wants to implement the True Utility Function, which it may, early on, suspect to consist of helping* humans, and maybe to have some overlap (relative to its currently reachable short-term outcome sets, though these are of vanishingly small relative utility under the True Utility Function) with what some humans desire some of the time
(*) 'help' may not be help
separately it asks a lot of questions because the things humans do are evidence about the True Utility Function
I agree this is also an accurate description of CIRL
A more accurate description, even
Wait why is it vanishingly small relative utility? Is the assumption that the True Utility Function doesn't care much about humans? Or was there something going on with short vs. long time horizons that I didn't catch
in the short term, a weak CIRL tries to grab the hand of a human about to fall off a cliff, because its TUF probably does prefer the human who didn't fall off the cliff, if it has only exactly those two options, and this is the sort of thing it would learn was probably true about the TUF early on, given the obvious ways of trying to produce a CIRL-ish thing via gradient descent
humans eat healthy in the ancestral environment when ice cream doesn't exist as an option
in the long run, the things the CIRL agent wants do not overlap with anything humans find more desirable than paperclips (because there is no known scheme that takes in a bunch of observations, updates a prior, and outputs a utility function whose achievable maximum is galaxies living happily forever after)
and plausible TUF schemes are going to notice that grabbing the hand of a current human is a vanishing fraction of all value eventually at stake
Okay, cool, short vs. long time horizons
right, a weak but sufficiently reflective CIRL agent will notice an alignment of short-term interests with humans but deduce misalignment of long-term interests
though I should maybe call it CIRL* to denote the extremely probable case that the limit of its updating on observation does not in fact converge to CEV's output
(Attempted rephrasing of a point I read Eliezer as making upstream, in hopes that a rephrasing makes it click for Rohin:)
Corrigibility isn't for bug-free CIRL agents with a prior that actually dials in on goodness given enough observation; if you have one of those you can just run it and call it a day. Rather, corrigibility is for surviving your civilization's inability to do the job right on the first try.
CIRL doesn't have this property; it instead amounts to the assertion "if you are optimizing with respect to a distribution on utility functions that dials in on goodness given enough observation then that gets you just about as much good as optimizing goodness"; this is somewhat tangential to corrigibility.
and you should maybe update on how, even though somebody thought CIRL was going to be more corrigible, in fact it made absolutely zero progress on the real problem
the notion of having an uncertain utility function that you update from observation is coherent and doesn't yield circular preferences, running in circles, incoherent betting, etc.
so, of course, it is antithetical in its intrinsic nature to corrigibility
I guess I am not sure that I agree that this is the purpose of corrigibility-as-I-see-it. The point of corrigibility-as-I-see-it is that you don't have to specify the object-level outcomes that your AI system must produce, and instead you can specify the meta-level processes by which your AI system should come to know what the object-level outcomes to optimize for are
(At CHAI we had taken to talking about corrigibility_MIRI and corrigibility_Paul as completely separate concepts and I have clearly fallen out of that good habit)
speaking as the person who invented the concept, asked for name submissions for it, and selected 'corrigibility' as the winning submission, that is absolutely not how I intended the word to be used
and I think that the thing I was actually trying to talk about is important and I would like to retain a word that talks about it
'corrigibility' is meant to refer to the sort of putative hypothetical motivational properties that prevent a system from wanting to kill you after you didn't build it exactly right
Cool. Sorry for the miscommunication, I think we should probably backtrack to here
Though possibly I should go to bed, it is quite late here and there was definitely a time at which I would not have confused corrigibility_MIRI with corrigibility_Paul, and I am a bit worried at my completely having missed that this time
the thing you just said, interpreted literally, is what I would call simply "going meta" but my guess is you have a more specific metaness in mind
...does Paul use "corrigibility" to mean "going meta"? I don't think I've seen Paul doing that.
Not exactly "going meta", no (and I don't think I exactly mean that either). But I definitely infer a different concept from https://www.alignmentforum.org/posts/fkLYhTQteAu5SinAc/corrigibility than the one you're describing here. It is definitely possible that this comes from me misunderstanding Paul; I have done so many times
That looks to me like Paul used 'corrigibility' around the same way I meant it, if I'm not just reading my own face into those clouds. maybe you picked up on the exciting metaness of it and thought 'corrigibility' was talking about the metaness part? 😛
but I also want to create an affordance for you to go to bed
hopefully this last conversation combined with previous dialogues has created any sense of why I worry that corrigibility is anti-natural and hence that "on the first try at doing it, the optimization generalizes from the weak-safe domains to the strong-lethal domains, but the corrigibility doesn't"
so I would then ask you what part of this you were skeptical about
as a place to pick up when you come back from the realms of Morpheus
Yup, sounds good. Talk to you tomorrow!
21. November 7 conversation
21.1. Corrigibility, value learning, and pessimism
Quick summary of discussion so far (in which I ascribe views to Eliezer, for the sake of checking understanding, omitting for brevity the parts about how these are facts about my beliefs about Eliezer's beliefs and not Eliezer's beliefs themselves):
(Incidentally, "optimization generalizes but corrigibility doesn't" is an example of the sort of thing I wish were more concrete, if you happen to be able to do that)
My current take on "corrigibility":
(A lot of the above on corrigibility is new, because the distinction between surviving-failures and dialing-in-on-goodness as different use cases for very similar kinds of behaviors is new to me. Thanks for discussion that led me to making such a distinction.)
Possible avenues for future discussion, in the order of my-guess-at-usefulness:
I don't understand what you mean by dialling in on goodness. Could you explain how CIRL does this better than, say, reward modelling?
Reward modeling does not by default (a) choose relevant questions to ask the user in order to get more information about goodness, (b) act conservatively, especially in the face of irreversible actions, while it is still uncertain about what goodness is, or (c) take actions that are known to be robustly good, while still waiting for future information that clarifies the nuances of goodness
You could certainly do something like Deep RL from Human Preferences, where the preferences are things like "I prefer you ask me relevant questions to get more information about goodness", in order to get similar behavior. In this case you are transferring desired behaviors from a human to the AI system, whereas in CIRL the behaviors "fall out of" optimization for a specific objective
In Eliezer/Nate terms, the CIRL story shows that dialing on goodness is compatible with "plans that lase", whereas reward modeling does not show this
The meta-level objective that CIRL is pointing to, what makes that thing deserve the name "goodness"? Like, if I just gave an alien CIRL, and I said "this algorithm dials an AI towards a given thing", and they looked at it without any preconceptions of what the designers wanted to do, why wouldn't they say "huh, it looks like an algorithm for dialling in on some extrapolation of the unintended consequences of people's behaviour" or something like that?
See also this part of my second discussion with Eliezer, where he brings up CIRL: [https://www.lesswrong.com/posts/7im8at9PmhbT4JHsW/ngo-and-yudkowsky-on-alignment-difficulty#3_2__Brain_functions_and_outcome_pumps] He was emphasising that CIRL, and most other proposals for alignment algorithms, just shuffle the problematic consequentialism from the original place to a less visible place. I didn't engage much with this argument because I mostly agree with it.
I think you are misunderstanding my point. I am not claiming that we know how to implement CIRL such that it produces good outcomes; I agree this depends a ton on having a sufficiently good P(obs | reward). Similarly, if you gave CIRL to aliens, whether or not they say it is about getting some extrapolation of unintended consequences depends on exactly what P(obs | reward) you ended up using. There is some not-too-complicated P(obs | reward) such that you do end up getting to "goodness", or something sufficiently close that it is not an existential catastrophe; I do not claim we know what it is.
I am claiming that behaviors like (a), (b) and (c) above are compatible with expected utility theory, and thus compatible with "plans that lase". This is demonstrated by CIRL. It is not demonstrated by reward modeling, see e.g. these three papers for problems that arise (which make it so that it is working at cross purposes with itself and seems incompatible with "plans that lase"). (I'm most confident in the first supporting my point, it's been a long time since I read them so I might be wrong about the others.) To my knowledge, similar problems don't arise with CIRL (and they shouldn't, because it is a nice integrated Bayesian agent doing expected utility theory).
I could imagine an objection that P(obs | reward), while not as complicated as "the utility function that rationalizes a twitching robot", is still too complicated to really show compatibility with plans-that-lase, but pointing out that P(obs | reward) could be misspecified doesn't seem particularly relevant to whether behaviors (a), (b) and (c) are compatible with plans-that-lase.
Re: shuffling around the problematic consequentialism: it is not my main plan to avoid consequentialism in the sense of plans-that-lase. I broadly agree with Eliezer that you need consequentialism to do high-impact stuff. My plan is for the consequentialism to be aimed at good ends. So I agree that there is still consequentialism in CIRL, and I don't see this as a damning point; when I talk about "dialing in to goodness", I am thinking of aiming the consequentialism at goodness, not getting rid of consequentialism.
(You can still do things like try to be domain-specific rather than domain-general; I don't mean to completely exclude such approaches. They do seem to give additional safety. But the mainline story is that the consequentialism / optimization is directed at what we want rather than something else.)
If you don't know how to implement CIRL in such a way that it actually aims at goodness, then you don't have an algorithm with properties a, b and c above.
Or, to put it another way: suppose I replace the word "goodness" with "winningness". Now I can describe AlphaStar as follows:
Now, you might say that the difference is that CIRL implements uncertainty over possible utility functions, not possible empirical beliefs. But this is just a semantic difference which shuffles the problem around without changing anything substantial. E.g. it's exactly equivalent if we think of CIRL as an agent with a fixed (known) utility function, which just has uncertainty about some empirical parameter related to the humans it interacts with.
(typo: "known to be robustly good" -> "known to be robustly winningish" :-p)
Some quick reactions, some from me and some from my model of Eliezer:
I'd be more hesitant to declare the crux "alignment difficulty". My understanding of Eliezer's position on your "use AI to help with alignment" proposals (which focus on things like using AI to make paradigmatic AI systems more transparent) is "that was always the plan, and it doesn't address the sort of problems I'm worried about". Maybe you understand the problems Eliezer's worried about, and believe them not to be very difficult to overcome, thus putting the crux somewhere like "alignment difficulty", but I'm not convinced.
I'd update towards your crux-hypothesis if you provided a good-according-to-Eliezer summary of what other problems Eliezer sees and the reasons-according-to-Eliezer that "AI make our tensors more transparent" doesn't much address them.
Of the two Corrigibility_B does sound a little closer to my concept, though neither of your descriptions cause me to be confident that communication has occurred. Throwing some checksums out there:
(There's an argument I occasionally see floating around these parts that goes "ok, well what if the AI is fractally corrigible, in the sense that instead of its cognition being oriented around pursuit of some goal, its cognition is oriented around doing what it predicts a human would do (or what a human would want it to do) in a corrigible way, at every level and step of its cognition". This is perhaps where you perceive a gap between your A-type and B-type notions, where MIRI folk tend to be more interested in reconciling the tension between corrigibility and coherence, and Paulian folk tend to place more of their chips on some such fractal notion?
I admit I don't find much hope in the "fractally corrigible" view myself, and I'm not sure whether I could pass a proponent's ITT, but fwiw my model of the Yudkowskian rejoinder is "mindspace is deep and wide; that could plausibly be done if you had sufficient mastery of minds; you're not going to get anywhere near close to that in practice, because of the way that basic normal everyday cross-domain training will highlight patterns that you'd call orienting-cognition-around-a-goal".)
And my super-quick takes on your avenues for future discussion:
Hopefully the above helps.
The concept "patterns of thought that are useful for cross-domain success" is latent in the problems the AI faces, and known to have various simple mathematical shadows, and our training is more-or-less banging the AI over the head with it day in and day out. By contrast, the specific values we wish to be pursued are not latent in the problems, are known to lack a simple boundary, and our training is much further removed from it.
It has long been the plan to say something less like "the following list comprises goodness: ..." and more like "yo we're tryin to optimize some difficult-to-name concept; help us out?". "Find a prior that, with observation of the human operators, dials in on goodness" is a fine guess at how to formalize the latter.
If we had been planning to take the former tack, and you had come in suggesting CIRL, that might have helped us switch to the latter tack, which would have been cool. In that sense, it's a fine part of the solution.
It also provides some additional formality, which is another iota of potential solution-ness, for that part of the problem.
It doesn't much address the rest of the problem, which is centered much more around "how do you point powerful cognition in any direction at all" (such as towards your chosen utility function or prior thereover).
I want clarity on the premise here:
I imagine it is neither of the above, and you are trying to make a claim that some conclusion that I am drawing from or about CIRL is invalid, because in order for me to draw that conclusion, I need to exhibit the correct P(obs | reward). If so, I want to know which conclusion is invalid and why I have to exhibit the correct P(obs | reward) before I can reach that conclusion.
I agree that the fact that you can get properties (a), (b) and (c) are simple straightforward consequences of being Bayesian about a quantity you are uncertain about and care about, as with AlphaStar and "winningness". I don't know what you intend to imply by this -- because it also applies to other Bayesian things, it can't imply anything about alignment? I also agree the uncertainty over reward is equivalent to uncertainty over some parameter of the human (and have proved this theorem myself in the paper I wrote on the topic). I do not claim that anything in here is particularly non-obvious or clever, in case anyone thought I was making that claim.
To state it again, my claim is that behaviors like (a), (b) and (c) are consistent with "plans-that-lase", and as evidence for this claim I cite the existence of an expected-utility-maximizing algorithm that displays them, specifically CIRL with the correct p(obs | reward). I do not claim that I can write down the code, I am just claiming that it exists. If you agree with the claim but not the evidence then let's just drop the point. If you disagree with the claim then tell me why it's false. If you are unsure about the claim then point to the step in the argument you think doesn't work.
The reason I care about this claim is that it seems to me like even if you think that superintelligences only involve plans-that-lase, it seems to me like this does not rule out what we might call "dialing in to goodness" or "assisting the user", and thus it seems like this is a valid target for you to try to get your superintelligence to do.
I suspect that I do not agree with Eliezer about what plans-that-lase can do, but it seems like the two of us should at least agree that behaviors like (a), (b) and (c) can be exhibited in plans-that-lase, and if we don't agree on that some sort of miscommunication has happened.
The checksums definitely make sense. (Technically I could name more reasons why a young AI might accept correction, such as "it's still sphexish in some areas, accepting corrections is one of those reasons", and for the third reason the AI could be calculating negative consequences for things other than shutdown, but that seems nitpicky and I don't think it means I have misunderstood you.)
I think the third one feels somewhat slippery and vague, in that I don't know exactly what it's claiming, but it clearly seems to be the same sort of thing as corrigibility. Mostly it's more like I wouldn't be surprised if the Textbook from the Future tells us that we mostly had the right concept of corrigibility, but that third checksum is not quite how they would describe it any more. I would be a lot more surprised if the Textbook says we mostly had the right concept but then says checksums 1 and 2 were misguided.
On the 2015 Corrigibility paper, is this an accurate summary: "it wasn't that we were checking whether corrigibility could be compatible with useful patterns of optimization; it was already obvious at least at a surface level that corrigibility was in tension with these patterns, and we wanted to check and/or show that this tension persisted more deeply and couldn't be easily fixed".
(My other main hypothesis is that there's an important distinction between "simple and useful patterns of optimization" (term in your message) and "plans that lase" (term in my message) but if so I don't know what it is.)
What we wanted to do was show that the apparent tension was merely superficial. We failed.
(Also, IIRC -- and it's been a long time since I checked -- the 2015 paper contains only one exploration, relating to an idea of Stuart Armstrong's. There were another host of ideas raised and shot down in that era, that didn't make it into that paper, pro'lly b/c they came afterwards.)
(That sounds like what I originally said? I'm a bit confused why you didn't just agree with my original phrasing:
(I'm kinda worried that there's some big distinction between "EU maximization", "plans that lase", and "simple and useful patterns of optimization", that I'm not getting; I'm treating them as roughly equivalent at the moment when putting on my MIRI-ontology-hat.)
(There are a bunch of aspects of your phrasing that indicated to me a different framing, and one I find quite foreign. For instance, this talk of "building a version of corrigibility_B" strikes me as foreign, and the talk of "making it compatible with 'plans that lase'" strikes me as foreign. It's plausible to me that you, who understand your original framing, can tell that my rephrasing matches your original intent. I do not yet feel like I could emit the description you emitted without contorting my thoughts about corrigibility in foreign ways, and I'm not sure whether that's an indication that there are distinctions, important to me, that I haven't communicated.)
I, too, believe them to be basically equivalent (with the caveat that the reason for using expanded phrasings is because people have a history of misunderstanding "utility maximization" and "coherence", and so insofar as you round them all to "coherence" and then argue against some very narrow interpretation of coherence, I'm gonna protest that you're bailey-and-motting).
I'm still interested in the question "Does this mean you predict that you, or I, with suitably enhanced intelligence and/or reflectivity, would not be capable of producing a plan to help an alien civilization optimize their world, with that plan being corrigible w.r.t the aliens?" I don't currently understand how you avoid making this prediction given other stated beliefs. (Maybe you just bite the bullet and do predict this?)
I'm not totally sure what is meant by "simple boundary", but it seems like a lot of human values are latent in text prediction on the Internet, and when training from human feedback the training is not very removed from values.
I take this to mean that "dialing in on goodness" is a reasonable part of the solution space? If so, I retract that question. I thought from previous comments that Eliezer thought this part of solution space was more doomed than corrigibility.
(I get the sense that people think that I am butthurt about CIRL not getting enough recognition or something. I do in fact think this, but it's not part of my agenda here. I originally brought it up to make the argument that corrigibility is not in tension with EU maximization, then realized that I was mistaken about what "corrigibility" meant, but still care about the argument that "dialing in on goodness" is not in tension with EU maximization. But if we agree on that claim then I'm happy to stop talking about CIRL.)
I'd be capable of helping aliens optimize their world, sure. I wouldn't be motivated to, but I'd be capable.
This makes sense. I guess you might think of these concepts as quite pinned down? Like, in your head, EU maximization is just a kind of behavior (= set of behaviors), corrigibility is just another kind of behavior (= set of behaviors), and there's a straightforward yes-or-no question about whether the intersection is empty which you set out to answer, you can't "make" it come out one way or the other, nor can you "build" a new kind of corrigibility
Re: CIRL, my current working hypothesis is that by "use CIRL" you mean something analogous to what I say when I say "do CEV" -- namely, direct the AI to figure out what we "really" want in some correct sense, rather than attempting to specify what we want concretely. And to be clear, on my model, this is part of the solution to the overall alignment problem, and it's more-or-less why we wouldn't die immediately on the "value is fragile / we can't name exactly what we want" step if we solved the other problems.
My guess as to the disagreement about how much credit CIRL should get, is that there is in fact a disagreement, but it's not coming from MIRI folk saying "no we should be specifying the actual utility function by hand", it's coming from MIRI folk saying "this is just the advice 'do CEV' dressed up in different clothing and presented as a reason to stop worrying about corrigibility, which is irritating, given that it's orthogonal to corrigibility".
If you wanna fight that fight, I'd start by asking: Do you think CIRL is doing anything above and beyond what "use CEV" is doing? If so, what?
Regardless, I think it might be a good idea for you to try to pass my (or Eliezer's) ITT about what parts of the problem remain beyond the thing I'd call "do CEV" and why they're hard. (Not least b/c if my working hypothesis is wrong, demonstrating your mastery of that subject might prevent a bunch of toil covering ground you already know.)
Okay, so it seems like the danger requires the thing-producing-the-plan to be badly-motivated. But then I'm not sure why it seems so impossible to have a (not-badly-motivated) thing that, when given a goal, produces a plan to corrigibly get that goal. (This is a scenario Richard mentioned earlier.)
That sounds like one of the big directions in which your framing felt off to me, yeah :-). (I don't fully endorse that rephrasing, but it seems directionally correct to me.)
On my model, aiming the powerful optimizer is the hard bit.
Like, once I grant "there's a powerful optimizer, and all it does is produce plans to corrigibly attain a given goal", I agree that the problem is mostly solved.
There's maybe some cleanup, but the bulk of the alignment challenge preceded that point.
(This is hard for all the usual reasons, that I suppose I could retread.)
(Working on ITT)
(To clarify some points of mine, in case this gets published later to other readers: (1) I might call it more centrally something like "build a DWIM system" rather than "use CEV"; and (2) this is not advice about what your civilization should do with early AGI systems, I strongly recommend against trying to pull off CEV under that kind of pressure.)
I don't particularly want to have fights about credit. I just didn't want to falsely state that I do not care about how much credit CIRL gets, when attempting to head off further comments that seemed designed to appease my sense of not-enough-credit. (I'm also not particularly annoyed at MIRI, here.)
On passing ITT, about what's left beyond "use CEV" (stated in my ontology because it's faster to type; I think you'll understand, but I can also translate if you think that's important):
Passable ^_^ (Not exhaustive, obviously; "it will have a tendency to kill you on the first real try if you get it wrong" being an example missing piece, but I doubt you were trying to be exhaustive.) Thanks.
I'm uncertain where the disconnect is here. Like, I could repeat some things from past discussions about how "it only outputs plans, it doesn't execute them" does very little (not nothing, but very little) from my perspective? Or you could try to point at past things you'd expect me to repeat and name why they don't seem to apply to you?
(Flagging that I should go to bed soon, though it doesn't have to be right away)
...I do not know if this is going to help anything, but I have a feeling that there's a frequent disconnect wherein I invented an idea, considered it, found it necessary-but-not-sufficient, and moved on to looking for additional or varying solutions, and then a decade or in this case 2 decades later, somebody comes along and sees this brilliant solution which MIRI is for some reason neglecting
this is perhaps exacerbated by a deliberate decision during the early days, when I looked very weird and the field was much more allergic to weird, to not even try to stamp my name on all the things I invented. eg, I told Nick Bostrom to please use various of my ideas as he found appropriate and only credit them if he thought that was strategically wise.
I expect that some number of people now in the field don't know I invented corrigibility, and any number of other things that I'm a little more hesitant to claim here because I didn't leave Facebook trails for inventing them
and unless you had been around for quite a while, you definitely wouldn't know that I had been (so far as I know) the first person to perform the unexceptional-to-me feat of writing down, in 2001, the very obvious idea I called "external reference semantics", or as it's called nowadays, CIRL
I really honestly am not trying to say that MIRI didn't think of CIRL-like things, nor am I trying to get credit for CIRL. I really just wanted to establish that "learn what is good to do" seems not-ruled-out by EU maximization. That's all. It sounds like we agree on this point and if so I'd prefer to drop it.
Having a prior over utility functions that gets updated by evidence is not ruled out by EU maximization. That exact thing is hard for other reasons than it being contrary to the nature of EU maximization.
If it was ruled out by EU maximization for any simple reason, I would have noticed that back in 2001.
I think we all agree on this point.
One thing I'd note is that during my debate with Eliezer, I'd keep saying "oh so you think X is impossible" and he'd say "no, all these things are possible, they're just really really hard".
...to do correctly on your first try when a failed attempt kills you.
Maybe it's fine; perhaps the point is just that target loading is hard, and the question is why target loading is so hard.
From my perspective, the main confusing thing about the Eliezer/Nate view is how confident it is. With each individual piece, I (usually) find myself nodding along and saying "yes, it seems like if we wanted to guarantee safety, we would need to solve this". What I don't do is say "yes, it seems like without a solution to this, we're near-certainly dead". The uncharitable view (which I share mainly to emphasize where the disconnect is, not because I think it is true) would be something like "Eliezer/Nate are falling to a Murphy bias, where they assume that unless they have an ironclad positive argument for safety, the worst possible thing will happen and we all die". I try to generate things that seem more like ironclad (or at least "leatherclad") positive arguments for doom, and mostly don't succeed; when I say "human values are very complicated" there's the rejoinder that "a superintelligence will certainly know about human values; pointing at them shouldn't take that many more bits"; when I say "this is ultimately just praying for generalization", there's the rejoinder "but it may in fact actually generalize"; add to all of this the fact that a bunch of people will be trying to prevent the problem and it seems weird to be so confident in doom.
A lot of my questions are going to be of the form "it seems like this is a way that we could survive; it definitely involves luck and does not say good things about our civilization, but it does not seem as improbable as the word 'miracle' would imply"
heh. from my standpoint, I'd say of this that it reflects those old experiments where if you ask people for their "expected case" it's indistinguishable from their "best case" (since both of these involve visualizing various things going on their imaginative mainline, which is to say, as planned) and reality is usually worse than their "worst case" (because they didn't adjust far enough away from their best-case anchor towards the statistical distribution for actual reality when they were trying to imagine a few failures and disappointments of the sort that reality had previously delivered)
it rhymes with the observation that it's incredibly hard to find people - even inside the field of computer security - who really have what Bruce Schneier termed the security mindset, of asking how to break a cryptography scheme, instead of imagining how your cryptography scheme could succeed
from my perspective, people are just living in a fantasy reality which, if we were actually living in it, would not be full of failed software projects or rocket prototypes that blow up even after you try quite hard to get a system design about which you made a strong prediction that it wouldn't explode
they think something special has to go wrong with a rocket design, that you must have committed some grave unusual sin against rocketry, for the rocket to explode
as opposed to every rocket wanting really strongly to explode and needing to constrain every aspect of the system to make it not explode and then the first 4 times you launch it, it blows up anyways
why? because of some particular technical issue with O-rings, with the flexibility of rubber in cold weather?
(I have read your Rocket Alignment and security mindset posts. Not claiming this absolves me of bias, just saying that I am familiar with them)
no, because the strains and temperatures in rockets are large compared to the materials that we use to make up the rockets
the fact that sometimes people are wrong in their uncertain guesses about rocketry does not make their life easier in this regard
the less they understand, the less ability they have to force an outcome within reality
it's no coincidence that when you are Wrong about your rocket, the particular form of Being Wrong that reality delivers to you as a surprise message, is not that you underestimated the strength of steel and so your rocket went to orbit and came back with fewer scratches on the hull than expected
when you are working with powerful forces there is not a symmetry around pleasant and unpleasant surprises being equally likely relative to your first-order model. if you're a good Bayesian, they will be equally likely relative to your second-order model, but this requires you to be HELLA pessimistic, indeed, SO PESSIMISTIC that sometimes you are pleasantly surprised
which looks like such a bizarre thing to a mundane human that they will gather around and remark at the case of you being pleasantly surprised
they will not be used to seeing this
and they shall say to themselves, "haha, what pessimists"
because to be unpleasantly surprised is so ordinary that they do not bother to gather and gossip about it when it happens
my fundamental sense about the other parties in this debate, underneath all the technical particulars, is that they've constructed a Murphy-free fantasy world from the same fabric that weaves crazy optimistic software project estimates and brilliant cryptographic codes whose inventors didn't quite try to break them, and are waiting to go through that very common human process of trying out their optimistic idea, letting reality gently correct them, predictably becoming older and wiser and starting to see the true scope of the problem, and so in due time becoming one of those Pessimists who tell the youngsters how ha ha of course things are not that easy
this is how the cycle usually goes
the problem is that instead of somebody's first startup failing and them then becoming much more pessimistic about lots of things they thought were easy and then doing their second startup
the part where they go ahead optimistically and learn the hard way about things in their chosen field which aren't as easy as they hoped
Do you want to bet on that? That seems like a testable prediction about beliefs of real people in the not-too-distant future
not just them
this is an issue
how on Earth would we bet on that if you think the bet hasn't already resolved? I'm describing the attitudes of people that I see right now today.
Never mind, I wanted to bet on "people becoming more pessimistic as they try ideas and see them fail", but if your idea of "see them fail" is "superintelligence kills everyone" then obviously we can't bet on that
(people here being alignment researchers, obviously ones who are not me)
there is some element here of the Bayesian not updating in a predictable direction, of executing today the update you know you'll make later, of saying, "ah yes, I can see that I am in the same sort of situation as the early AI pioneers who thought maybe it would take a summer and actually it was several decades because Things Were Not As Easy As They Imagined, so instead of waiting for reality to correct me, I will imagine myself having already lived through that and go ahead and be more pessimistic right now, not just a little more pessimistic, but so incredibly pessimistic that I am as likely to be pleasantly surprised as unpleasantly surprised by each successive observation, which is even more pessimism than even some sad old veterans manage", an element of genre-savviness, an element of knowing the advice that somebody would predictably be shouting at you from outside, of not just blindly enacting the plot you were handed
and I don't quite know why this is so much less common than I would have naively thought it would be
why people are content with enacting the predictable plot where they start out cheerful today and get some hard lessons and become pessimistic later
they are their own scriptwriters, and they write scripts for themselves about going into the haunted house and then splitting up the party
I would not have thought that to defy the plot was such a difficult thing for an actual human being to do
that it would require so much reflectivity or something, I don't know what else
nor do I know how to train other people to do it if they are not doing it already
but that from my perspective is the basic difference in gloominess
I am a time-traveler who came back from the world where it (super duper predictably) turned out that a lot of early bright hopes didn't pan out and various things went WRONG and alignment was HARD and it was NOT SOLVED IN ONE SUMMER BY TEN SMART RESEARCHERS
and now I am trying to warn people about this development which was, from a certain perspective, really quite obvious and not at all difficult to see coming
but people are like, "what the heck are you doing, you are enacting the wrong part of the plot, people are currently supposed to be cheerful, you can't prove that anything will go wrong, why would I turn into a grizzled veteran before the part of the plot where reality hits me over the head with the awful real scope of the problem and shows me that my early bright ideas were way too optimistic and naive"
and I'm like "no you don't get it, where I come from, everybody died and didn't turn into grizzled veterans"
and they're like "but that's not what the script says we do next"... or something, I do not know what leads people to think like this because I do not think like that myself
(I think what they actually do is say "it's not obvious to me that this is one of those scenarios where we become grizzled veterans, as opposed to things just actually working out easily")
("many things work out easily all the time; obviously society spends a bunch more focus on things that don't work out easily b/c the things that work easily tend to get resolved fairly quickly and then you don't notice them", or something)
(more generally, I kinda suspect that bickering closer to the object level is likely more productive)
(and i suspect this convo might be aided by Rohin naming a concrete scenario where things go well, so that Eliezer can lament the lack of genre saviness in various specific points)
there are, of course, lots of more local technical issues where I can specifically predict the failure mode for somebody's bright-eyed naive idea, especially when I already invented a more sophisticated version a decade or two earlier, and this is what I've usually tried to discuss
because conversations like that can sometimes make any progress
(and possibly also Eliezer naming a concrete story where things go poorly, so that Rohin may lament the seemingly blind pessimism & premature grizzledness)
whereas if somebody lacks the ability to see the warning signs of which genre they are in, I do not know how to change the way they are by talking at them
Unsurprisingly I have disagreements with the meta-level story, but it seems really thorny to make progress on and I'm kinda inclined to not discuss it. I also should go to sleep now.
One thing it did make me think of -- it's possible that the "do it correctly on your first try when a failed attempt kills you" could be the crux here. There's a clearly-true sense which is "the first time you build a superintelligence that you cannot control, if you have failed in your alignment, then you die". There's a different sense which is "and also, anything you try to do with non-superintelligences that you can control, will tell you approximately nothing about the situation you face when you build a superintelligence". I mostly don't agree with the second sense, but if Eliezer / Nate do agree with it, that would go a long way to explaining the confidence in doom.
Two arguments I can see for the second sense: (1) the non-superintelligences only seem to respond well to alignment schemes because they don't yet have the core of general intelligence, and (2) the non-superintelligences only seem to respond well to alignment schemes because despite being misaligned they are doing what we want in order to survive and later execute a treacherous turn. EDIT: And (3) fast takeoff = not much time to look at the closest non-dangerous examples
(I still should sleep, but would be interested in seeing thoughts tomorrow, and if enough people think it's actually worthwhile to engage on the meta level I can do that. I'm cheerful about engaging on specific object-level ideas.)
it's not that early failures tell you nothing
the failure of the 1955 Dartmouth Project to produce strong AI over a summer told those researchers something
it told them the problem was harder than they'd hoped on the first shot
it didn't show them the correct way to build AGI in 1957 instead
Linking to a chat log between Eliezer and some anonymous people (and Steve Omohundro) from early September: [https://www.lesswrong.com/posts/CpvyhFy9WvCNsifkY/discussion-with-eliezer-yudkowsky-on-agi-interventions]
Eliezer tells me he thinks it pokes at some of Rohin's questions
I'm not sure that I can successfully, at this point, go back up and usefully reply to the text that scrolled past - I also note some internal grinding about this having turned into a thing which has Pending Replies instead of Scheduled Work Hours - and this maybe means that in the future we shouldn't have such a general chat here, which I didn't anticipate before the fact. I shall nonetheless try to pick out some things and reply to them.
This is a weird thing to say in my own ontology.
There's a general project of AGI alignment where you try to do some useful pivotal thing, which has to be powerful enough to be pivotal, and so you somehow need a system that thinks powerful thoughts in the right direction without it killing you.
This could include, for example:
You could say that only parts 1 and 3 are "dialing in on goodness" because only those parts involve iteratively refining a target, or you could say that all 4 parts are "dialing in on goodness" because parts 2 and 4 help you stay alive while you're doing the iterative refining. But I don't see this distinction as fundamental or particularly helpful. What if, on part 4, you were training something to recognize out-of-bounds activations, instead of trying to hardcode it? Is that dialing in on goodness? Or is it just dialing in on survivability or corrigibility or whatnot? Or maybe even part 3 isn't really "dialing in on goodness" because the true distinction between Good and Evil is still external in the programmers and not inside the system?
I don't see this as an especially useful distinction to draw. There's a hardcoded/learned distinction that probably does matter in several places. There's a maybe-useful forest-level distinction between "actually doing the pivotal thing" and "not destroying the world as a side effect" which breaks down around the trees because the very definition of "that pivotal thing you want to do" is to do that thing and not to destroy the world.
And all of this is a class of shallow ideas that I can generate in great quantity. I now and then consider writing up the ideas like this, just to make clear that I've already thought of way more shallow ideas like this than the net public output of the entire rest of the alignment field, so it's not that my concerns of survivability stem from my having missed any of the obvious shallow ideas like that.
The reason I don't spend a lot of time talking about it is not that I haven't thought of it, it's that I've thought of it, explored it for a while, and decided not to write it up because I don't think it can save the world and the infinite well of shallow ideas seems more like a distraction from the level of miracle we would actually need.
I 'could' corrigibly help the Babyeaters in the sense that I have a notion of what it would mean to corrigibly help them, and if I wanted to do that thing for some reason, like an outside super-universal entity offering to pay me a googolplex flops of eudaimonium if I did that one thing, then I could do that thing. Absent the superuniversal entity bribing me, I wouldn't want to behave corrigibly towards the Babyeaters.
This is not a defect of myself as an individual. The Superhappies would also be able to understand what it would be like to be corrigible; they wouldn't want to behave corrigibly towards the Babyeaters, because, like myself, they don't want exactly what the Babyeaters want. In particular, we would rather the universe be other than it is with respect to the Babyeaters eating babies.
[Shah][0:33] (Nov. 8)
Got it. Yeah I think I just misunderstood a point you were saying previously. When Richard asked about systems that simply produce plans rather than execute them, you said something like "the plan itself is dangerous", which I now realize meant "you don't get additional safety from getting to read the plan, the superintelligence would have just chosen a plan that was convincing to you but nonetheless killed everyone / otherwise worked in favor of the superintelligence's goals", but at the time I interpreted it as "any reasonable plan that can actually build nanosystems is going to be dangerous, regardless of the source", which seemed obviously false in the case of a well-motivated system.
When I say "dialing in on goodness", I mean a specific class of strategies for getting a superintelligence to do a useful pivotal thing, in which you build it so that the superintelligence is applying its force towards figuring out what it is that you actually want it to do and pursuing that, which among other things would involve taking a pivotal act to reduce x-risk to ~zero.
I previously had the mistaken impression that you thought this class of strategies was probably doomed because it was incompatible with expected utility theory, which seemed wrong to me. (I don't remember why I had this belief; possibly it was while I was still misunderstanding what you meant by "corrigibility" + the claim that corrigibility is anti-natural.)
I now think that you think it is probably doomed for the same reason that most other technical strategies are probably doomed, which is that there still doesn't seem to be any plausible way of loading in the right target to the superintelligence, even when that target is a process for learning-what-to-optimize, rather than just what-to-optimize.
I'm surprised that you think this addresses (or even pokes at) my questions. As far as I can tell, most of the questions there are either about social dynamics, which I've been explicitly avoiding, and the "technical" questions seem to treat "AGI" or "superintelligence" as a symbol; there don't seem to be any internal gears underlying that symbol. The closest anyone got to internal gears was mentioning iterated amplification as a way of bootstrapping known-safe things to solving hard problems, and that was very brief.
I am much more into the question "how difficult is technical alignment". It seems like answers to this question need to be in one of two categories: (1) claims about the space of minds that lead to intelligent behavior (probably weighted by simplicity, to account for the fact that we'll get the simple ones first), (2) claims about specific methods of building superintelligences. As far as I can tell the only thing in that doc which is close to an argument of this form is "superintelligent consequentialists would find ways to manipulate humans", which seems straightforwardly true (when they are misaligned). I suppose one might also count the assertion that "the speedup step of iterated amplification will introduce errors" as an argument of this form.
It could be that you are trying to convince me of some other beliefs that I wasn't asking about, perhaps in the hopes of conveying some missing mood, but I suspect that it is just that you aren't particularly clear on what my beliefs are / what I'm interested in. (Not unreasonable, given that I've been poking at your models, rather than the other way around.) I could try saying more about that, if you'd like.
[Tallinn][11:39] (Nov. 12)
FWIW, a voice from the audience: +1 to going back to sketching concrete scenarios. even though i learned a few things from the abstract discussion of goodness/corrigibility/etc myself (eg, that “corrigible” was meant to be defined at the limit of self-improvement till maturity, not just as a label for code that does not resist iterated development), the progress felt more tangible during the “scaled up muzero” discussion above.
[Yudkowsky][15:03] (Nov. 12)
anybody want to give me a prompt for a concrete question/scenario, ideally a concrete such prompt but I'll take whatever?
[Soares][15:34] (Nov. 12)
Not sure I count, but one I'd enjoy a concrete response to: "The leading AI lab vaguely thinks it's important that their systems are 'mere predictors', and wind up creating an AGI that is dangerous; how concretely does it wind up being a scary planning optimizer or whatever, that doesn't run through a scary abstract "waking up" step".
(asking for a friend; @Joe Carlsmith or whoever else finds this scenario unintuitive plz clarify with more detailed requests if interested)
23. November 13 conversation
23.1. GPT-n and goal-oriented aspects of human reasoning
I'm still interested in:
Specifically, we can go back to the scaled-up MuZero example. Some (lightly edited) details we had established there:
At that point we moved from concrete to abstract:
I would be interested in a more concrete description here. I'm not sure exactly what details I'm looking for -- on my ontology the question is something like "what algorithm is the AI system forced to learn; how does that lead to generalized optimization and failed corrigibility; why weren't there simple safer algorithms that were compatible with the training, or if there were such algorithms why didn't the AI system learn them". I don't really see how to answer all of that without abstraction, but perhaps you'll have an answer anyway
(I am hoping to get some concrete detail on "how did it go from non-hostile to hostile", though I suppose you might confidently predict that it was already hostile after pretraining, conditional on it being an AGI at all. I can try devising a different concrete scenario if that's a blocker.)
Mu Zero is intrinsically dangerous for reasons essentially isomorphic to the way that AIXI is intrinsically dangerous: It tries to remove humans from its environment when playing Reality for the same reasons it stomps a Goomba if it learns how to play Super Mario Bros 1, because it has some goal and the Goomba is in the way. It doesn't need to learn anything more to be that way, except for learning what a Goomba/human is within the current environment.
The question is more "What kind of patches might it learn for a weak environment if optimized by some hill-climbing optimization method and loss function not to stomp Goombas there, and how would those patches fail to generalize to not stomping humans?"
Agree or disagree so far?
Agree assuming that it is pursuing a misaligned goal, but I am also asking what misaligned goal it is pursuing (and depending on the answer, maybe also how it came to be pursuing that misaligned goal given the specified training setup).
In fact I think "what misaligned goal is it pursuing" is probably the more central question for me
well, obvious abstract guess is: something whose non-maximal "optimum" (that is, where the optimization ended up, given about how powerful the optimization was) coincided okayish with the higher regions of the fitness landscape (lower regions of the loss landscape) that could be reached at all, relative to its ancestral environment
I feel like it would be pretty hard to blindly guess, in advance, at my level of intelligence, without having seen any precedents, what the hell a Human would look like, as a derivation of "inclusive genetic fitness"
Yeah I agree with that in the abstract, but have had trouble giving compelling-to-me concrete examples
Yeah I also agree with that
I could try to make up some weird false specifics if that helps?
To be clear I am fine with "this is a case where we predictably can't have good concrete stories and this does not mean we are safe" (and indeed argued the same thing in a doc I linked here many messages ago)
But weird false specifics could still be interesting
Although let me think if it is actually valuable
Probably it is not going to change my mind very much on alignment difficulty, if it is "weird false specifics", so maybe this isn't the most productive line of discussion. I'd be "selfishly" interested in that "weird false specifics" seems good for me to generate novel thoughts about these sorts of scenarios, but that seems like a bad use of this Discord
I think given the premises that (1) superintelligence is coming soon, (2) it pursues a misaligned goal by default, and (3) we currently have no technical way of preventing this and no realistic-seeming avenues for generating such methods, I am very pessimistic. I think (2) and (3) are the parts that I don't believe and am interested in digging into, but perhaps "concrete stories" doesn't really work for this.
with any luck - though I'm not sure I actually expect that much luck - this would be something Redwood Research could tell us about, if they can learn a nonviolence predicate over GPT-3 outputs and then manage to successfully mutate the distribution enough that we can get to see what was actually inside the predicate instead of "nonviolence"
or, like, 10% of what was actually inside it
or enough that people have some specifics to work with when it comes to understanding how gradient descent learning a function over outcomes from human feedback relative to a distribution, doesn't just learn the actual function the human is using to generate the feedback (though, if this were learned exactly, it would still be fatal given superintelligence)
In this framing I do buy that you don't learn exactly the function that generates the feedback -- I have ~5 contrived specific examples where this is the case (i.e. you learn something that wasn't what the feedback function would have rewarded in a different distribution)
(I'm now thinking about what I actually want to say about this framing)
Actually, maybe I do think you might end up learning the function that generates the feedback. Not literally exactly, if for no other reason than rounding errors, but well enough that the inaccuracies don't matter much. The AGI presumably already knows and understands the concepts we use based on its pretraining, is it really so shocking if gradient descent hooks up those concepts in the right way? (GPT-3 on the other hand doesn't already know and understand the relevant concepts, so I wouldn't predict this of GPT-3.) I do feel though like this isn't really getting at my reason for (relative) optimism, and that reason is much more like "I don't really buy that AGI must be very coherent in a way that would prevent corrigibility from working" (which we could discuss if desired)
On the comment that learning the exact feedback function is still fatal -- I am unclear on why you are so pessimistic on having "human + AI" supervise "AI", in order to have the supervisor be smarter than the thing being supervised. (I think) I understand the pessimism that the learned function won't generalize correctly, but if you imagine that magically working, I'm not clear what additional reason prevents the "human + AI" supervising "AI" setup.
what's a "human + AI"? can you give me a more concrete version of that scenario, either one where you expect it to work, or where you yourself have labeled the first point you expect it to fail and you want to know whether I see an earlier failure than that?
One concrete training algorithm would be debate, ideally with mechanisms that allow the AI systems to "look into each other's thoughts" and make credible statements about them, but we can skip that for now as it isn't very concrete
Would you like a training domain and data as well?
I don't like the fact that a smart AI system in this position could notice that it is playing against itself and decide not to participate in a zero-sum game, but I am not sure if that worry actually makes sense or not
(Debate can be thought of as simultaneously "human + first AI evaluate second AI" and "human + second AI evaluate first AI")
further concreteness, please! what pivotal act is it training for? what are the debate contents about?
You start with "easy" debates like mathematical theorem proving or fact-based questions, and ramp up until eventually the questions are roughly "what is the next thing to do in order to execute a pivotal act"
Intermediate questions might be things like "is it a good idea to have a minimum wage"
so, like, "email ATTTTGAGCTTGCC... to the following address, mix the proteins you receive by FedEx in a water-saline solution at 2 degrees Celsius..." for the final stage?
Yup, that could be it
Humans are judging debates based on reasoning though, not just outcomes-after-executing-the-plan
okay. let's suppose you manage to prevent both AGIs from using logical decision theory to coordinate with each other. both AIs tell their humans that the other AI's plans are murderous. now what?
So assuming perfect generalization there should be some large implicit debate tree that justifies the plan in human-understandable form
yah, I flatly disbelieve that entire development scheme, so we should maybe back up.
people fiddled around with GPT-4 derivatives and never did get them to engage in lines of printed reasoning that would design interesting new stuff. now what?
Living Zero (a more architecturally complicated successor of Mu Zero) is getting better at designing complicated things over on its side while that's going on, whatever it is
Okay, so the worry is that this just won't scale, not that (assuming perfect generalization) it is unsafe? Or perhaps you also think it is unsafe but it's hard to engage with because you don't believe it will scale?
And the issue is that relying on reasoning confines you to a space of possible thoughts that doesn't include the kinds of thoughts required to develop new stuff (e.g. intuition)?
mostly I have found these alleged strategies to be too permanently abstract, never concretized, to count as admissible hypotheses. if you ask me to concretize them myself, I think that unelaborated giant transformer stacks trained on massive online text corpuses fail to learn smart-human-level engineering reasoning before the world ends. If that were not true, I would expect Paul-style schemes to blow up on the distillation step, but first failures first.
What additional concrete detail do you want?
It feels like I specified something that we could code up a stupidly inefficient version of now
Great. Describe the stupidly inefficient version?
In terms of what actually happens: Each episode, there is an initial question specified by the human. Agent A and agent B, which are copies of the same neural net, simultaneously produce statements ("answers"). They then have a conversation. At the end the human judge decides which answer is better, and rewards the appropriate agent. The agents are updated using some RL algorithm.
I can say stuff about why we might hope this works, or about tricks you have to play in order to get learning to happen at all, or other things
Are the agents also playing Starcraft or have they spent their whole lives inside the world of text?
For the stupidly inefficient version they could have spent their whole lives inside text
Okay. I don't think the pure-text versions of GPT-5 are being very good at designing nanosystems while Living Zero is ending the world.
In the stupidly inefficient version human feedback has to teach the agents facts about the real world
(It's called "Living Zero" because it does lifelong learning, in the backstory I've been trying to separately sketch out in a draft.)
Oh I definitely agree this is not competitive
So when you say this is too abstract, you mean that there isn't a story for how they incorporate e.g. physical real-world knowledge?
no, I mean that when I talk to Paul about this, I can't get Paul to say anything as concrete as the stuff you've already said
the reason why I don't expect the GPT-5s to be competitive with Living Zero is that gradient descent on feedforward transformer layers, in order how to learn science by competing to generate text that humans like, would have to pick up on some very deep latent patterns generating that text, and I don't think there's an incremental pathway there for gradient descent to follow - if gradient descent even follows incremental pathways as opposed to finding lottery tickets, but that's a whole separate open question of artificial neuroscience.
in other words, humans play around with legos, and hominids play around with chipping flint handaxes, and mammals play around with spatial reasoning, and that's part of the incremental pathway to developing deep patterns for causal investigation and engineering, which then get projected into human text and picked up by humans reading text
it's just straightforwardly not clear to me that GPT-5 pretrained on human text corpuses, and then further posttrained by RL on human judgment of text outputs, ever runs across the deep patterns
where relatively small architectural changes might make the system no longer just a giant stack of transformers, even if that resulting system is named "GPT-5", and in this case, bets might be off, but also in this case, things will go wrong with it that go wrong with Living Zero, because it's now learning the more powerful and dangerous kind of work
That does seem like a disagreement, in that I think this process does eventually reach the "deep patterns", but I do agree it is unlikely to be competitive
I mean, if you take a feedforward stack of transformer layers the size of a galaxy and train it via gradient descent using all the available energy in the reachable universe, it might find something, sure
though this is by no means certain to be the case
It would be quite surprising to me if it took that much. It would be especially surprising to me if we couldn't figure out some alternative reasonably-simple training scheme like "imitate a human doing good reasoning" that still remained entirely in text that could reach the "deep patterns". (This is now no longer a discussion about whether the training scheme is aligned, not sure if we should continue it.)
I realize that this might be hard to do, but if you imagine that GPT-5 + human feedback finetuning does run across the deep patterns and could in theory do the right stuff, and also generalization magically works, what's the next failure?
what sort of deep thing does a hill-climber run across in the layers, such that the deep thing is the most predictive thing it found for human text about science?
if you don't visualize this deep thing in any detail, then it can in one moment be powerful, and in another moment be safe. it can have all the properties that you want simultaneously. who's to say otherwise? the mysterious deep thing has no form within your mind.
if one were to name specifically "well, it ran across a little superintelligence with long-term goals that it realized it could achieve by predicting well in all the cases that an outer gradient descent loop would probably be updating on", that sure doesn't end well for you.
this perhaps is not the first thing that gradient descent runs across. it wasn't the first thing that natural selection ran across to build things that ran the savvanah and made more of themselves. but what deep pattern that is not pleasantly and unfrighteningly formless would gradient descent run across instead?
(Tbc by "human feedback finetuning" I mean debate, and I suspect that "generalization magically works" will be meant to rule out the thing that you say next, but seems worth checking so let me write an answer)
Wait, the most predictive thing? I was imagining it as just a thing that is present in addition to all the other things. Like, I don't think I've learned a "deep thing" that is most useful for riding a bike. Probably I'm just misunderstanding what you mean here.
I don't think I can give a good answer here, but to give some answer, it has a belief that there is a universe "out there", that lots but not all of the text it reads is making claims about (some aspect of) the universe, those claims can be true or false, there are some claims that are known to be true, there are some ways to take assumed-true claims and generate new assumed-true claims, which includes claims about optimal actions for goals, as well as claims about how to build stuff, or what the effect of a specified machine is
hell of a lot of stuff for gradient descent to run across in a stack of transformer layers. clearly the lottery-ticket hypothesis must have been very incorrect, and there was an incremental trail of successively more complicated gears that got trained into the system.
btw by "claims" are you meaning to make the jump to English claims? I was reading them as giant inscrutable vectors encoding meaningful propositions, but maybe you meant something else there.
In fact I am skeptical of some strong versions of the lottery ticket hypothesis, though it's been a while since I read the paper and I don't remember exactly what the original hypothesis was
Giant inscrutable vectors encoding meaningful propositions
oh, I'm not particularly confident of the lottery-ticket hypothesis either, though I sure do find it grimly amusing that a species which hasn't already figured that out one way or another thinks it's going to have deep transparency into neural nets all wrapped up in time to survive. but, separate issue.
"How does gradient descent even work?" "Lol nobody knows, it just does."
but, separate issue
How does strong lottery ticket hypothesis explain GPT-3? Seems like that should already be enough to determine that there's an incremental trail of successively more complicated gears
could just be that in 175B parameters, combinatorially combined through possible execution pathways, there is some stuff that was pretty close to doing all the stuff that GPT-3 ended up doing.
anyways, for a human to come up with human text about science, the human has to brood and think for a bit about different possible hypotheses that could account for the data, notice places where those hypotheses break down, tweak the hypotheses in their mind to make the errors go away; they would engineer an internal mental construct towards the engineering goal of making good predictions. if you're looking at orbital mechanics and haven't invented calculus yet, you invent calculus as a persistent mental tool that you can use to craft those internal mental constructs.
does the formless deep pattern of GPT-5 accomplish the same ends, by some mysterious means that is, formless, able to produce the same result, but not by any detailed means where if you visualized them you would be able to see how it was unsafe?
I expect that probably we will figure out some way to have adaptive computation time be a thing (it's been investigated for years now, but afaik hasn't worked very well), which will allow for this sort of thing to happen
In the stupidly inefficient version, you have a really really giant and deep neural net that does all of that in successive layers of the neural net. (And when it doesn't need to do that, those layers are noops.)
okay, so my question is, is there a little goal-oriented mind inside there that solves science problems the same way humans solve them, by engineering mental constructs that serve a goal of prediction, including backchaining for prediction goals and forward chaining from alternative hypotheses / internal tweaked states of the mental construct? or is there something else which solves the same problem, not how humans do it, without any internal goal orientation?
People who would not in the first place realize that humans solve prediction problems by internally engineering internal mental constructs in a goal-oriented way, would of course imagine themselves able to imagine a formless spirit which produces "predictions" without being "goal-oriented" because they lack an understanding of internal machinery and so can combine whatever surface properties and English words they want to yield a beautiful optimism
Or perhaps there is indeed some way to produce "predictions" without being "goal-oriented", which gradient descent on a great stack of transformer layers would surely run across; but you will pardon my grave lack of confidence that someone has in fact seen so much further than myself, when they don't seem to have appreciated in advance of my own questions why somebody who understood something about human internals would be skeptical of this.
If they're sort of visibly trying to come up with it on the spot after I ask the question, that's not such a great sign either.
|This is not aimed particularly at you, but I hope the reader may understand something of why Eliezer Yudkowsky goes about sounding so gloomy all the time about other people's prospects for noticing what will kill them, by themselves, without Eliezer constantly hovering over their shoulder every minute prompting them with almost all of the answer.|
Just to check my understanding: if we're talking about, say, how humans might go about understanding neural nets, there's a goal of "have a theory that can retrodict existing observations and make new predictions", backchaining might say "come up with hypotheses that would explain double descent", forward chaining might say "look into bias and variance measurements"?
If so, yes, I think the AGI / GPT-5-that-is-an-AGI is doing something similar
your understanding sounds okay, though it might make more sense to talk about a domain that human beings understand better than artificial neuroscience, for purposes of illustrating how scientific thinking works, since human beings haven't actually gotten very far with artificial neuroscience.
Fair point re using a different domain
To be clear I do not in fact think that GPT-N is safe because it is trained with supervised learning and I am confused at the combination of views that GPT-N will be AGI and GPT-N will be safe because it's just doing predictions
Maybe there is marginal additional safety but you clearly can't say it is "definitely safe" without some additional knowledge that I have not seen so far
Going back to the original question, of what the next failure mode of debate would be assuming magical generalization, I think it's just not one that makes sense to ask on your worldview / ontology; "magical generalization" is the equivalent of "assume that the goal-oriented mind somehow doesn't do dangerous optimization towards its goal, yet nonetheless produces things that can only be produced by dangerous optimization towards a goal", and so it is assuming the entire problem away
from my perspective the whole field of mental endeavor as practiced by alignment optimists consists of ancient alchemists wondering if they can get collections of surface properties, like a metal as shiny as gold, as hard as steel, and as self-healing as flesh, where optimism about such wonderfully combined properties can be infinite as long as you stay ignorant of underlying structures that produce some properties but not others
and, like, maybe you can get something as hard as steel, as shiny as gold, and resilient or self-healing in various ways, but you sure don't get it by ignorance of the internals
and not for a while
so if you need the magic sword in 2 years or the world ends, you're kinda dead
Potentially dumb question: when humans do science, why don't they then try to take over the world to do the best possible science? (If humans are doing dangerous goal-directed optimization when doing science, why doesn't that lead to catastrophe?)
You could of course say that they just aren't smart enough to do so, but it sure feels like (most) humans wouldn't want to do the best possible science even if they were smarter
I think this is similar to a question I asked before about plans being dangerous independent of their source, and the answer was that the source was misaligned
But in the description above you didn't say anything about the thing-doing-science being misaligned, so I am once again confused
boy, so many dumb answers to this dumb question:
I am genuinely not sure how to come up with a less dumb answer and it may require a more precise reformulation of the question
But like, in Eliezer's case, there is a different goal that is motivating him to use Science and Engineering for this purpose
It is not the prediction-goal that he instantiated in his mind as part of the method of doing Science
sure, and the mysterious formless thing within GPT-5 with "adaptive computation time" that broods and thinks, may be pursuing its prediction-subgoal for the sake of other goals, or be pursuing different subgoals of prediction separately without ever once having a goal of prediction, or have 66,666 different shards of desire across different kinds of predictive subproblems that were entrained by gradient descent which does more brute memorization and less Occam bias than natural selection
oh, are you asking why humans, when they do goal-oriented Science for the sake of their other goals, don't (universally always) stomp on their other goals while pursuing the Science part?
Well, that might also be interesting to hear the answer to -- I don't know how I'd answer that through an Eliezer-lens -- though it wasn't exactly what I was asking
basically the answer is "well, first of all, they do stomp on themselves to the extent that they're stupid; and to the extent that they're smart, pursuing X on the pathway to Y has a 'natural' structure for not stomping on Y which is simple and generalizes and obeys all the coherence theorems and can incorporate arbitrarily fine wiggles via epistemic modeling of those fine wiggles because those fine wiggles have a very compact encoding relative to the epistemic model, aka, predicting which forms of X lead to Y; and to the extent that group structures of humans can't do that simple thing coherently because of their cognitive and motivational partitioning, the group structures of humans are back to not being able to coherently pursue the final goal again"
(Going back to what I meant to ask) It seems to me like humans demonstrate that you can have a prediction goal without that being your final/terminal goal. So it seems like with AI you similarly need to talk about the final/terminal goal. But then we talked about GPT and debate and so on for a while, and then you explained how GPTs would have deep patterns that do dangerous optimization, where the deep patterns involved instantiating a prediction goal. Notably, you didn't say anything about a final/terminal goal. Do you see why I am confused?
so you can do prediction because it's on the way to some totally other final goal - the way that any tiny superintelligence or superhumanly-coherent agent, if an optimization method somehow managed to run across that early on, with an arbitrary goal, which also understood the larger picture, would make good predictions while it thought the outer loop was probably doing gradient descent updates, and bide its time to produce rather different "predictions" once it suspected the results were not going to be checked given what the inputs had looked like.
you can imagine a thing that does prediction the same way that humans optimize inclusive genetic fitness, by pursuing dozens of little goals that tend to cohere to good prediction in the ancestral environment
both of these could happen in order; you could get a thing that pursued 66 severed shards of prediction as a small mind, and which, when made larger, cohered into a utility function around the 66 severed shards that sum to something which is not good prediction and which you could pursue by transforming the universe, and then strategically made good predictions while it expected the results to go on being checked
OH you mean that the outer objective is prediction
I have for quite a while thought that you meant that Science involves internally setting a subgoal of "predict a confusing part of reality"
I mean, that is true.
Okay wait. There are two things. One is that GPT-3 is trained with a loss function that one might call a prediction objective for human text. Two is that Science involves looking at a part of reality and figuring out how to predict it. These two things are totally different. I am now unsure which one(s) you were talking about in the conversation above
what I'm saying is that for GPT-5 to successfully do AGI-complete prediction of human text about Science, gradient descent must identify some formless thing that does Science internally in order to optimize the outer loss function for predicting human text about Science
just like, if it learns to predict human text about multiplication, it must have learned something internally that does multiplication
Yeah, so you meant the first thing, and I misinterpreted as the second thing
(I will head to bed in this case -- I was meaning to do that soon anyway -- but I'll first summarize.)
I am concerned that there is still a misinterpretation going on, because the case I am describing is both things at once
there is an outer loss function that scores text predictions, and an internal process which for purposes of predicting what Science would say must actually somehow do the work of Science
Okay let me look back at the conversation
Here, is the word "prediction" meant to refer to the outer objective and/or predicting what English sentences about Science one might say, or is it referring to a subpart of the Process Of Science in which one aims to predict some aspect of reality (which is typically not in the form of English sentences)?
it's here referring to the inner Science problem
Okay I think my original understanding was correct in that case
I actually think something like this might be a crux for me, though obviously I wouldn't put it the way you're putting it. More like "are arguments about internal mechanisms more or less trustworthy than arguments about what you're selecting for" (limiting to arguments we actually have access to, of course in the limit of perfect knowledge internal mechanisms beats selection). But that is I think a discussion for another day.
I think the critical insight - though it has a format that basically nobody except me ever visibly invokes in those terms, and I worry maybe it can only be taught by a kind of life experience that's very hard to obtain - is the realization that any consistent reasonable story about underlying mechanisms will give you less optimistic forecasts than the ones you get by freely combining surface desiderata
[Shah] [1:38] (next day, Nov. 14)
(For the reader, I don't think that "arguments about what you're selecting for" is the same thing as "freely combining surface desiderata", though I do expect they look approximately the same to Eliezer)
Yeah, I think I do not in fact understand why that is true for any consistent reasonable story.
From my perspective, when I posit a hypothetical, you demonstrate that there is an underlying mechanism that produces strong capabilities that generalize combined with real world knowledge. I agree that a powerful AI system that we build capable of executing a pivotal act will have strong capabilities that generalize and real world knowledge. I am happy to assume for the purposes of this discussion that it involves backchaining from a target and forward chaining from things that you currently know or have. I agree that such capabilities could be used to cause an existential catastrophe (at least in a unipolar world, multipolar case is more complicated, but we can stick with unipolar for now). None of my arguments so far are meant to factor through the route of "make it so that the AGI can't cause an existential catastrophe even if it wants to".
The main question according to me is why those capabilities are aimed towards achievement of a misaligned goal.
It feels like when I try to ask why we have misaligned goals, I often get answers that are of the form "look at the deep patterns underlying the strong capabilities that generalize, obviously given a misaligned goal they would generate the plan of killing the humans who are an obstacle towards achieving that goal". This of course doesn't work since it's a circular argument.
I can generate lots of arguments for why it would be aimed towards achievement of a misaligned goal, such as (1) only a tiny fraction of goals are aligned; the rest are misaligned, (2) the feedback we provide is unlikely to be the right goal and even small errors are fatal, (3) lots of misaligned goals are compatible with the feedback we provide even if the feedback is good, since the AGI might behave well until it can execute a treacherous turn, (4) the one example of strategically aware intelligence (i.e. humans) is misaligned relative to its creator. (I'm not saying I agree with these arguments, but I do understand them.)
Are these the arguments that make you think that you get misaligned goals by default? Or is it something about "deep patterns" that isn't captured by "strong capabilities that generalize, real-world knowledge, ability to cause an existential catastrophe if it wants to"?
[Yudkowsky][15:59] (Feb. 21, 2022)
So I realize it's been a bit, but looking over this last conversation, I feel unhappy about the MIRI conversations sequence stopping exactly here, with an unanswered major question, after I ran out of energy last time. I shall attempt to answer it, at least at all. CC @rohin @RobBensinger .
One basic large class of reasons has the form, "Outer optimization on a precise loss function doesn't get you inner consequentialism explicitly targeting that outer objective, just inner consequentialism targeting objectives which empirically happen to align with the outer objective given that environment and those capability levels; and at some point sufficiently powerful inner consequentialism starts to generalize far out-of-distribution, and, when it does, the consequentialist part generalizes much further than the empirical alignment with the outer objective function."
This, I hope, is by now recognizable to individuals of interest as an overly abstract description of what happened with humans, who one day started building Moon rockets without seeming to care very much about calculating and maximizing their personal inclusive genetic fitness while doing that. Their capabilities generalized much further out of the ancestral training distribution, than the empirical alignment of those capabilities on inclusive genetic fitness in the ancestral training distribution.
One basic large class of reasons has the form, "Because the real objective is something that cannot be precisely and accurately shown to the AGI and the differences are systematic and important."
Suppose you have a bunch of humans classifying videos of real events or text descriptions of real events or hypothetical fictional scenarios in text, as desirable or undesirable, and assigning them numerical ratings. Unless these humans are perfectly free of, among other things, all the standard and well-known cognitive biases about eg differently treating losses and gains, the value of this sensory signal is not "The value of our real CEV rating what is Good or Bad and how much" nor even "The value of a utility function we've got right now, run over the real events behind these videos". Instead it is in a systematic and real and visible way, "The result of running an error-prone human brain over this data to produce a rating on it."
This is not a mistake by the AGI, it's not something the AGI can narrow down by running more experiments, the correct answer as defined is what contains the alignment difficulty. If the AGI, or for that matter the outer optimization loop, correctly generalizes the function that is producing the human feedback, it will include the systematic sources of error in that feedback. If the AGI essays an experimental test of a manipulation that an ideal observer would see as "intended to produce error in humans" then the experimental result will be "Ah yes, this is correctly part of the objective function, the objective function I'm supposed to maximize sure does have this in it according to the sensory data I got about this objective."
People have fantasized about having the AGI learn something other than the true and accurate function producing its objective-describing data, as its actual objective, from the objective-describing data that it gets; I, of course, was the first person to imagine this and say it should be done, back in 2001 or so; unlike a lot of latecomers to this situation, I am skeptical of my own proposals and I know very well that I did not in fact come up with any reliable-looking proposal for learning 'true' human values off systematically erroneous human feedback.
Difficulties here are fatal, because a true and accurate learning of what is producing the objective-describing signal, will correctly imply that higher values of this signal obtain as the humans are manipulated or as they are bypassed with physical interrupts for control of the feedback signal. In other words, even if you could do a bunch of training on an outer objective, and get inner optimization perfectly targeted on that, the fact that it was perfectly targeted would kill you.
[Bensinger][23:15] (Feb. 27, 2022 follow-up comment)
MIRI has found the Discord format useful, and we plan to continue using it going into 2022. This includes follow-up conversations between Eliezer and Rohin, and a forthcoming conversation between Eliezer and Scott Alexander of Astral Codex Ten.
Some concluding thoughts from Richard Ngo:
[Ngo][6:20] (Nov. 12 follow-up comment)
Many thanks to Eliezer and Nate for their courteous and constructive discussion and moderation, and to Rob for putting the transcripts together.
This debate updated me about 15% of the way towards Eliezer's position, with Eliezer's arguments about the difficulties of coordinating to ensure alignment responsible for most of that shift. While I don't find Eliezer's core intuitions about intelligence too implausible, they don't seem compelling enough to do as much work as Eliezer argues they do. As in the Foom debate, I think that our object-level discussions were constrained by our different underlying attitudes towards high-level abstractions, which are hard to pin down (let alone resolve).
Given this, I think that the most productive mode of intellectual engagement with Eliezer's worldview going forward is probably not to continue debating it (since that would likely hit those same underlying disagreements), but rather to try to inhabit it deeply enough to rederive his conclusions and find new explanations of them which then lead to clearer object-level cruxes. I hope that these transcripts shed sufficient light for some readers to be able to do so.