abramdemski(Abram Demski)

• abramdemski 7 May 2021 15:32 UTC

  LW: 7 AF: 5

  AF

  on: My AGI Threat Model: Misal­igned Model-Based RL Agent

  (Much of this has been touched on already in our Discord conversation:)

  Inner alignment problem: The value function might be different from the reward function.

  In fact that’s an understatement: The value function will be different from the reward function. Why? Among other things, because they have different type signatures—they accept different input!

  Surely this isn’t relevant! We don’t by any means want the value function to equal the reward function. What we want (at least in standard RL) is for the value function to be the solution to the dynamic programming problem set up by the reward function and world model (or, more idealistically, the reward function and the actual world).

  • The value function is a function of the latent variables in the world-model—thus, even abstract concepts like “differentiate both sides of the equation” are assigned values. The value function is updated by the reward signals, using (I assume) some generalization of TD learning (definition).

  While something like this seems possible, it strikes me as a better fit for systems that do explicit probabilistic reasoning, as opposed to NNs. Like, if we’re talking about predicting what ML people will do, the sentence “the value function is a function of the latent variables in the world model” makes a lot more sense than the clarification “even abstract concepts are assigned values”. Because it makes more sense for the value to be just another output of the same world-model NN, or perhaps, to be a function of a “state vector” produced by the world-model NN, or maybe a function taking the whole activation vector of the world-model NN at a time-step as an input, as opposed to a value function which is explicitly creating output values for each node in the value function NN (which is what it sounds like when you say even abstract concepts are assigned values).

  I assume that the learned components (world-model, value function, planner /​ actor) continue to be updated in deployment—a.k.a. online learning (definition). This is important for the risk model below, but seems very likely—indeed, unavoidable—to me:

  This seems pretty implausible to me, as we’ve discussed. Like, yes, it might be a good research direction, and it isn’t terribly non-prosaic. However, the current direction seems pretty focused on offline learning (even RL, which was originally intended specifically for online learning, has become a primarily offline method!!), and GPT-3 has convinced everyone that the best way to get online learning is to do massive offline training and rely on the fact that if you train on enough variety, learning-to-learn is inevitable.

  • Online updating of the world-model is necessary for the AGI to have a conversation, learn some new idea from that conversation, and then refer back to that idea perpetually into the future.

  I think my GPT-3 example adequately addresses the first two points, and memory networks adequately address the third.

  • Online updating of the value function is then also necessary for the AGI to usefully employ those new concepts. For example, if the deployed AGI has a conversation in which it learns the idea of “Try differentiating both sides of the equation”, it needs to be able to assign and update a value for that new idea (in different contexts), in order to gradually learn how and when to properly apply it.

  • Online updating of the value function is also necessary for the AGI to break down problems into subproblems. Like if “inventing a better microscope” is flagged by the value function as being high-value, and then the planner notices that “If only I had a smaller laser, then I’d be able to invent a better microscope”, then we need a mechanism for the value function to flag “inventing a smaller laser” as itself high-value.

  These points are more interesting, but I think it’s plausible that architectural innovations could deal with them w/​o true online learning.

• abramdemski 6 May 2021 19:39 UTC

  LW: 3 AF: 3

  AF

  on: Pre­dic­tion can be Outer Aligned at Optimum

  I think this is pretty complicated, and stretches the meaning of several of the critical terms employed in important ways. I think what you said is reasonable given the limitations of the terminology, but ultimately, may be subtly misleading.

  How I would currently put it (which I think strays further from the standard terminology than your analysis):

  Take 1

  Prediction is not a well-defined optimization problem.

  Maximum-a-posteriori reasoning (with a given prior) is a well-defined optimization problem, and we can ask whether it’s outer-aligned. The answer may be “no, because the Solomonoff prior contains malign stuff”.

  Variational bayes (with a given prior and variational loss) is similarly well-defined. We can similarly ask whether it’s outer-aligned.

  Minimizing square loss with a regularizing penalty is well-defined. Etc. Etc. Etc.

  But “prediction” is not a clearly specified optimization target. Even if you fix the predictive loss (square loss, Bayes loss, etc) you need to specify a prior in order to get a well-defined expectation to minimize.

  So the really well-defined question is whether specific predictive optimization targets are outer-aligned at optimum. And this type of outer-alignment seems to require the target to discourage mesa-optimizers!

  This is a problem for the existing terminology, since it means these objectives are not outer-aligned unless they are also inner-aligned.

  Take 2

  OK, but maybe you object. I’m assuming that “optimization” means “optimization of a well-defined function which we can completely evaluate”. But (you might say), we can also optimize under uncertainty. We do this all the time. In your post, you frame “optimal performance” in terms of loss+distribution. Machine learning treats the data as a sample from the true distribution, and uses this as a proxy, but adds regularizers precisely because it’s an imperfect proxy (but the regularizers are still just a proxy).

  So, in this frame, we think of the true target function as the average loss on the true distribution (ie the distribution which will be encountered in the wild), and we think of gradient descent (and other optimization methods used inside modern ML) as optimizing a proxy (which is totally normal for optimization under uncertainty).

  With this frame, I think the situation gets pretty complicated.

  Take 2.1

  Sure, ok, if it’s just actually predicting the actual stuff, this seems pretty outer-aligned. Pedantic note: the term “alignment” is weird here. It’s not “perfectly aligned” in the sense of perfectly forwarding human values. But it could be non-malign, which I think is what people mostly mean by “AI alignment” when they’re being careful about meaning.

  Take 2.2

  But this whole frame is saying that once we have outer alignment, the problem that’s left is the problem of correctly predicting the future. We have to optimize under uncertainty because we can’t predict the future. An outer-aligned loss function can nonetheless yield catastrophic results because of distributional shift. The Solomonoff prior is malign because it doesn’t represent the future with enough accuracy, instead containing some really weird stuff.

  So, with this terminology, the inner alignment problem is the prediction problem. If we can predict well enough, then we can set up a proxy which gets us inner alignment (by heavily penalizing malign mesa-optimizers for their future treacherous turns). Otherwise, we’re stuck with the inner alignment problem.

  So given this use of terminology, “prediction is outer-aligned” is a pretty weird statement. Technically true, but prediction is the whole inner alignment problem.

  Take 2.3

  But wait, let’s reconsider 2.1.

  In this frame, “optimal performance” means optimal at deployment time. This means we get all the strange incentives that come from online learning. We aren’t actually doing online learning, but optimal performance would respond to those incentives anyway.

  (You somewhat circumvent this in your “extending the training distribution” section when you suggest proxies such as the Solomonoff distribution rather than using the actual future to define optimality. But this can reintroduce the same problem and more besides. Option #1, Solomonoff, is probably accurate enough to re-introduce the problems with self-fulfilling prophecies, besides being malign in other ways. Option #3, using a physical quantum prior, requires a solution to quantum gravity, and also is probably accurate enough to re-introduce the same problems with self-fulfilling prophecies as well. The only option I consider feasible is #2, human priors. Because humans could notice this whole problem and refuse to be part of a weird loop of self-fulfilling prediction.)

• abramdemski 6 May 2021 16:38 UTC

  2 points

  in reply to: Cato the Eider’s comment on: Death by Red Tape

  Oh, and for the FDA/​TSA/​etc, apologies for not being up to writing a more scathing review. This has to do with issues mentioned here. I welcome your more critical analysis if you’d want to write it. I sort of wrote the minimal thing I could. I do want to stand by the statement that it isn’t highly fine-tuned utilitarian optimization by any stretch (IE it’s not at all like Vernor Vinge’s vision of over-optimization), and also, that many relevant people actively prefer for the TSA to exist (eg politicians and people on the street will often give defenses like “it helps avert these extreme risks”).

  I’m not sure we disagree on anything. I don’t mean to imply that the TSA increases slack… Perhaps I over-emphasized the opposite-ness of my two scenarios. They are not opposite in every way.

  Death by No Slack:

  Utilitarian, puritan, detail-oriented (context-insensitive) thinking dominates everything. Goodhart’s curse is everywhere. Performance measurements. Tests. All procedures are evidence-based. Empirical history has a tendency to win the argument over careful reasoning (including in conversations about catastrophic risks, which means risks are often under-estimated). But we have longstanding institutions which have become highly optimized. Things have been in economic equilibrium for a long time. Everything is finely tuned. Things are close to their malthusian limit. People wouldn’t know how to deal with change.

  Death by Red Tape:

  Don’t swim 30 minutes after eating. Don’t fall asleep in a room with a fan going. The ultimate nanny state, regulating away anything which has been associated with danger in the past, unless it’s perceived as necessary for society to function, in which case it comes with paperwork and oversight. Climbing trees is illegal unless you have a license. If you follow all the rules you have a very high chance of dying peacefully in your bed. There’s a general sense that “follow all the rules” means “don’t do anything weird”. Any genuinely new idea gets the reaction “that sounds illegal”. Or “the insurance/​bank/​etc won’t like it”.

  Hm, these scenarios actually have a lot of similarities...

• abramdemski 6 May 2021 16:05 UTC

  2 points

  in reply to: Cato the Eider’s comment on: Death by Red Tape

  I like the analogy between social collapse and sand-pile collapse this implies :) [actually, rice-pile collapse] But can you say anything more about the model, eg, how you would make a simple computer simulation illustrating the dynamics? Based on your divorce example, it seems like the model is roughly “people sometimes form groups” (as opposed to “sometimes a new grain is dropped” in the rice-pile analogy). But how can we model the formation of very large groups, such as nations?

• abramdemski 6 May 2021 15:48 UTC

  2 points

  in reply to: Dentin’s comment on: Frac­tal Con­ver­sa­tions vs Holis­tic Response

  For bulk exchange of information and state, holistic is really good. I strongly prefer the holistic approach, but I’ve found that it only works for entirely friendly conversations.

  This is a good point. The holistic approach can come off as really adversarial if the conversation is just a little adversarial, because my blindsight guess can be pretty ugly, or at least, can come off that way. I have witnessed a fairly friendly seeming conversation where a holistic-responder responded to a decision theory point by bringing up trauma and abuse (bringing up episodes in the past of both conversation participants which you’d normally expect to be really sensitive) and offered a perspective which could at least very easily be confused with “it’s your fault you were abused”. If the conversation hadn’t been very friendly, this could have gone extremely poorly. Holistic responses have a tendency to

  If it’s adversarial, I find that branches get aggressively pruned to just the things that the opposing side can most easily attack.

  Yeah, I often find that I have to prune less-important threads preemptively, out of concern that my response on branch X might seem like an easy target and thus cause branch Y to get pruned by the other person, when I think branch Y is more important. To be honest, I probably do not do this as much as I ideally should. (I want to respond to all the threads!)

  So a level of non-adversarialness is also required to really maintain good branching conversations.

Frac­tal Con­ver­sa­tions vs Holis­tic Response

• abramdemski 2 May 2021 20:40 UTC

  3 points

  in reply to: Kaj_Sotala’s comment on: Death by Red Tape

  The ‘and them some’ is what causes the trouble. Complex societies collapse because, when some stress comes, those societies have become too inflexible to respond. In retrospect, this can seem mystifying. Why didn’t these societies just re-tool in less complex ways? The answer Tainter gives is the simplest one: When societies fail to respond to reduced circumstances through orderly downsizing, it isn’t because they don’t want to, it’s because they can’t.

  In such systems, there is no way to make things a little bit simpler – the whole edifice becomes a huge, interlocking system not readily amenable to change.

  I can’t help but think of The Dictator’s Handbook and how all of the societies examined were probably very far from democratic. The over-extraction of resources was probably relatively aligned with the interests of the ruling class. “The king neither hates you nor loves you, but your life is made up of value which can be extracted to keep the nobles from stabbing him in the back for another few years”

• abramdemski 2 May 2021 18:20 UTC

  2 points

  in reply to: Measure’s comment on: Death by Red Tape

  Agreed. Something something infrabayes.

  But,

  • my current estimate is that if the government were doing adversarial reasoning, they would have allocated the money much differently; they probably heavily over-reacted to the very specific attack that was observed

  • even under adversarial reasoning, a strategy isn’t much good if it costs more than what it prevents

  It’s practically impossible to objectively assess the cost-effectiveness of the TSA, since we have no idea what the alternate universe with no TSA looks like. But we can subjectively assess.

• abramdemski 2 May 2021 18:08 UTC

  2 points

  in reply to: aphyer’s comment on: Death by Red Tape

  I agree—I would want to account for stress from going thru TSA, a better accounting of life lost, etc. Unfortunately, a better analysis would have taken up a lot more space and perhaps been a post in itself. But I’m curious to see your analysis if you think you can produce one.

  My internal reasoning is more like “look, any way you run the numbers, so long as you’re reasonably fair, it aint gunna work out” but that’s not exactly an argument, just a strongly held intuition.

• abramdemski 1 May 2021 19:46 UTC

  21 points

  on: Your Dog is Even Smarter Than You Think

  I’ve been watching this with interest when youtube randomly serves me videos (I sometimes search youtube for things like “crows playing”, so I think the algorithm figured out that I like animal intelligence videos), but I wasn’t aware of everything you mentioned.

  imagines a future where people would be surprised to learn that humans thought animals couldn’t talk

Death by Red Tape

• abramdemski 1 May 2021 15:31 UTC

  LW: 4 AF: 3

  AF

  in reply to: Richard_Ngo’s comment on: Gra­da­tions of In­ner Align­ment Obstacles

  I tend to think of the latter as more compressed,

  I’m not sure what you meant by “more compressed”.

  I used to define “agent” as “both a searcher and a controller”, IE, something which uses an internal selection/​search of some kind to accomplish an external control task. This might be too restrictive, though.

• abramdemski 30 Apr 2021 16:42 UTC

  LW: 4 AF: 4

  AF

  in reply to: Daniel Kokotajlo’s comment on: Fun with +12 OOMs of Compute

  If the AI and compute trend is just a blip, then doesn’t that return us to the previous trend line in the graph you show at the beginning, where we progress about 2 ooms a decade? (More accurately, 1 oom every 6-7 years, or, 8 ooms in 5 decades.)

  Ignoring AI and compute, then: if we believe +12 ooms in 2016 means great danger in 2020, we should believe that roughly 75 years after 2016, we are at most four years from the danger zone.

  Whereas, if we extrapolate the AI-and-compute trend, +12 ooms is like jumping 12 years in the future; so the idea of risk by 2030 makes sense.

  So I don’t get how your conclusion can be so independent of AI-and-compute.

• abramdemski 30 Apr 2021 16:15 UTC

  LW: 2 AF: 2

  AF

  in reply to: Bunthut’s comment on: Iden­ti­fi­a­bil­ity Prob­lem for Su­per­ra­tional De­ci­sion Theories

  The “signals” players receive for correlated equilibria are already semantic. So I’m suspicious that they are better by calling on our intuition more to be used, with the implied risks. For example I remember reading about a result to the effect that correlated equilibria are easier to learn. This is not something we would expect from your explanation of the differences: If we explicitly added something (like the signals) into the game, it would generally get more complicated.

  It’s not something we would naively expect, but it does further speak in favor of CE, yes?

  In particular, if you look at those learnability results, it turns out that the “external signal” which the agents are using to correlate their actions is the play history itself. IE, they are only using information which must be available to learning agents (granted, sufficiently forgetful learning agents might forget the history; however, I do not think the learnability results actually rely on any detailed memory of the history—the result still holds with very simple agents who only remember a few parameters, with no explicit episodic memory (unlike, eg, tit-for-tat).

• abramdemski 30 Apr 2021 16:10 UTC

  LW: 2 AF: 2

  AF

  in reply to: Bunthut’s comment on: My Cur­rent Take on Counterfactuals

  I don’t understand this part. Your explanation of PCDT at least didn’t prepare me for it, it doesn’t mention betting. And why is the payoff for the counterfactual-2-boxing determined by the beliefs of the agent after 1-boxing?

  Not sure how to best answer. I’m thinking of all this in an LIDT setting, so all learning occurs through traders making bets. The payoff for 2-boxing is dependent on beliefs after 1-boxing because all share prices update every market day and the “payout” for a share is essentially what you can sell it for. Similarly, if a trader buys a share of an undecidable sentence (let’s say, the consistency of PA) then the only “payoff” is whatever you can sell it for later, based on future market prices, because the sentence will never get fully decided one way or the other.

  But how is the counterfactual supposed to actually think? I don’t think just having the agent unrevisably believe that crossing is counterfactually +10 is a reasonable answer, even if it doesn’t have any instrumental problems in this case.

  My claim is: eventually, if you observe enough cases of “crossing” in similar circumstances, your expectation for “cross” should be consistent with the empirical history (rather than, say, −10 even though you’ve never experienced −10 for crossing). To give a different example, I’m claiming it is irrational to persist in thinking 1-boxing gets you less money in expectation, if your empirical history continues to show that it is better on average.

  And I claim that if there is a persistent disagreement between counterfactuals and evidential conditionals, then the agent will in fact experimentally try crossing infinitely often, due to the value-of-information of testing the disagreement (that is, this will be the limiting behavior of reduced temporal discounting, under the assumption that the agent isn’t worried about traps).

  So the two will indeed converge (under those assumptions).

  And if we had an actual concrete model of counterfactual reasoning instead of a list of desiderata, it might be possible to make a troll based on the consistency of whatever is inside this model, as opposed to PA.

  The hope is that we can block the troll argument completely if proving B->A does not imply cf(A|B)=1, because no matter what predicate the troll uses, the inference from P to cf fails. So what we concretely need to do is give a version of counterfactual reasoning which lets cf(A|B) not equal 1 in some cases where B->A is proved.

  Granted, there could be some other problematic argument. However, if my learning-theoretic ideas go through, this provides another safeguard: Troll Bridge is a case where the agent never learns the empirical distribution, due to refusing to observe a specific case. If we know this never happens (given the learnability conditions), then this blocks off a whole range of Troll-Bridge-like arguments.

  I’m more worried about the embedding problems with the trader in dutch book arguments, so the one against CDT isn’t as decisive for me.

  [...]

  I also think there is a good chance the answer to the cartesian boundary problem won’t be “heres how to calculate where your boundary is”, but something else of which boundaries are an approximation, and then something similar would go for counterfactuals, and then there won’t be a counterfactual theory which respects embedding.

  This is a sensible position. I think this is similar to Scott G’s take on my direction.

  My argument would not be that the dutch book should be super compelling, but rather, that it appears we can do everything without questioning so many assumptions.

  For example, Scott would argue that probability is for things spacelike separated from you, so we need a different concept for thinking about consequences of actions. My argument is not anything against Scott’s concrete reasons to cast doubt on the broad applicability of probabilistic thinking; rather, my argument is “look at all the things we can do with probabilistic reasoning” (at least, suitably generalized).

  In particular, good learning-theoretic results can address concerns about decision-theoretic paradoxes; a convincing optimality result could and should systematically rule out a wide range of decision-theoretic paradoxes. So, if true, it could become difficult to motivate any additional worries about cartesian frames etc.

• abramdemski 30 Apr 2021 15:20 UTC

  LW: 4 AF: 4

  AF

  in reply to: Daniel Kokotajlo’s comment on: Gra­da­tions of In­ner Align­ment Obstacles

  (a) Maybe the deceptive ticket that makes T’ work is indeed there from the beginning, but maybe it’s outnumbered by ‘benign’ tickets, so that the overall behavior of the network is benign. This is an argument against premise 4, the idea being that even though the deceptive ticket scores just as well as the rest, it still loses out because it is outnumbered.

  My overall claim is that attractor-basin type arguments need to address the base case. This seems like a potentially fine way to address the base-case, if the math works out for whatever specific attractor-basin argument. If we’re trying to avoid deception via methods which can steer away from deception if we assume there’s not yet any deception, then we’re in trouble; the technique’s assumptions are violated.

  (b) Maybe the deceptive ticket that makes T’ work is not deceptive from the beginning, but rather is made so by the training process T’.

  Right, this seems in line with the original lottery ticket hypothesis, and would alleviate the concern. It doesn’t seem as consistent with the tangent space hypothesis, though.

• abramdemski 30 Apr 2021 15:12 UTC

  LW: 2 AF: 2

  AF

  in reply to: Pattern’s comment on: Gra­da­tions of In­ner Align­ment Obstacles

  I’m a bit confused about part of what we’re disagreeing on, so, context trace:

  I originally said:

  My model is that GPT-3 almost certainly is “hiding its intelligence” at least in small ways. For example, if its prompt introduces spelling mistakes, GPT-3 will ‘intentionally’ continue with more spelling mistakes in what it generates.

  Then you said:

  Yeah, because it’s goal is prediction. Within prediction there isn’t a right way to write a sentence. It’s not a spelling mistake, it’s a spelling prediction. (If you want it to not do that, then train it on...predicting the sentence, spelled correctly. Reward correct spelling, with a task of ‘seeing through the noise’. You could try going further, and reinforce a particular style, or ‘this word is better than that word’.)

  Then I said:

  Yes, I agree that GPT’s outer objective fn is misaligned with maximum usefulness, and a more aligned outer objective would make it do more of what we would want.

  However, I feel like your “if you don’t want that, then...” seems to suppose that it’s easy to make it outer-aligned. I don’t think so.

  The spelling example is relatively easy (we could apply an automated spellcheck to all the data, which would have some failure rate of course but is maybe good enough for most situations—or similarly, we could just apply a loss function for outputs which aren’t spelled correctly). But what’s the generalization of that?? How do you try to discourage all “deliberate mistakes”?

  Then you said:

  1. Make something that has a goal. Does AlphaGo make deliberate mistakes at Go? Or does it try to win, and always make the best move* (with possible the limitation that, it might not be as good at playing from positions it wouldn’t play itself into)?

  1. It seems like the discussion was originally about hidden information, not deliberate mistakes—deliberate mistakes were just an example of GPT taking information-hiding actions. I spuriously asked how to avoid all deliberate mistakes when what I intended had more to do with hidden information

  2. The claim I was trying to support in that paragraph was (as stated in the directly preceding paragraph) it isn’t easy to make it outer-aligned. AlphaGo isn’t outer-aligned.

  3. AlphaGo could be hiding a lot of information, like GPT. In AlphaGo’s case, information which AlphaGo doesn’t reveal to the user would include a lot of concepts about the state of the game, which aren’t revealed to human users easily. This isn’t particularly sinister, but, it is hidden information.

  4. A hypothetical more-data-efficient AlphaGo which was trained only on playing humans (rather than self-play) could have an internal psychological model of humans. This would be “inaccessible information”. It could also implement deliberate deception to increase its win rate.

  I get the vibe that I might be missing a broader point you’re trying to make. Maybe something like “you get what you ask for”—you’re pointing out that hiding information like this isn’t at all surprising given the loss function, and different loss functions imply different behavior, often in a straightforward way.

  If this were your point, I would respond:

  • The point of the inner alignment problem is that, it seems, you don’t always get what you ask for.

  • I’m not trying to say it’s surprising that GPT would hide things in this way. Rather, this is a way of thinking about how GPT thinks and how sophisticated/​coherent its internal world-model is (in contrast to what we can see by asking it questions). This seems like important, but indirect, information about inner optimizers.

  You think of the spelling errors as deception. Another way of characterizing it might be ‘trying to speak the lingo’. For example we might think of as an agent, that, if it chatted with you for a while, and you don’t use words like ‘aint’ a lot, might shift to not use words like that around you. (Is an agent that “knows its audience” deceptive? Maybe yes, maybe no.)

  You think that there is a correct way to spell words. GPT might be more agnostic.

  I’m not sure whether there is any disagreement here. Certainly I tend to think about language differently from that. But I agree that’s the purely descriptive view.

  I also lean towards ‘this thing was created, and given something like a goal, and it’s going to keep doing that goal like thing’. If it ‘spells things wrong to fit in’ that’s because it was trained as a predictor, not a writer.

  I mean, I agree as a statistical tendency, but are you assuming away the inner alignment problem?

  Given the way it ‘can respond to prompts’ characterizing it as ‘deceptive’ might make sense under some circumstances*, but if you’re going to look at it that way, training something to do ‘prediction’ (of original text) and then have it ‘write’ is systematically going to result in ‘deception’ because it has been trained to be a chameleon. To blend in.

  We seem to be in agreement about this.

  However, if it developed a model of the world, and it was possible to factor that out from the goal—then pulling the model out and getting ‘the truth’ is possible. But the two might not be separable. If trained on say “a flat earther dataset” will it say “the earth is round”? Can it actually achieve insight?

  Right, this is the question I am interested in. Is there a world model? (To what degree?)

• abramdemski 30 Apr 2021 13:54 UTC

  LW: 4 AF: 4

  AF

  in reply to: Richard_Ngo’s comment on: Gra­da­tions of In­ner Align­ment Obstacles

  I’m inclined to think so, mostly because terms shouldn’t be introduced unnecessarily. If we can already talk about systems that are capable/​competent at certain tasks, then we should just do that directly.

  Thinking about this more, I think maybe what I really want it to mean is: competent policies which are non-myopic in some sense. A truly myopic Q&A system doesn’t feel much like a controller /​ inner optimizer (even if it is misaligned, it’s not steering the world in a bad direction, because it’s totally myopic).

  I’m not sure what sense of “myopia” I want to use, though.

• abramdemski 30 Apr 2021 13:47 UTC

  2 points

  in reply to: Daniel Kokotajlo’s comment on: Pre­dic­tive Cod­ing has been Unified with Backpropagation

  4, 5: Whoa whoa, just because we humans do some non-bayesian stuff and some better-than-backprop stuff doesn’t mean that the brain isn’t running pure bayes nets or backprop-approximation or whatever at the low level! That extra fancy cool stuff we do could be happening at a higher level of abstraction. Networks in the brain learned via backprop-approximation could themselves be doing the logical induction stuff and the super-efficient-learning stuff. In which case we should expect that big NN’s trained via backprop might also stumble across similar networks which would then do similarly cool stuff.

  How could this address point #5? If GD is slow, then GD would be slow to learn faster learning methods.

  All of the following is intended as concrete examples against the pure-bayes-brain hypothesis, not as evidence against the brain doing some form of GD:

  1. One thing the brain could be doing under the hood is some form of RL using value-prop. This is difficult to represent in Bayes nets. The attempts I’ve seen end up making reward multiplicative rather than additive across time, which makes sense because Bayes nets are great at multiplying things but not so great at representing additive structures. I think this is OK (we could regard it as an exponential transform of usual reward) until we want to represent temporal discounting. Another problem with this is: representing via graphical models means representing the full distribution over reward values, rather than a point estimate. But this is inefficient compared with regular tabular RL.

  2. Another thing the brain could be doing under the hood is “memory-network” style reasoning which learns a policy for utilizing various forms of memory (visual working memory, auditory working memory, episodic memory, semantic memory...) for reasoning. Because this is fundamentally about logical uncertainty (being unsure about the outcome at the end of some mental work), it’s not very well-represented by Bayesian models. It probably makes more sense to use (model-free) RL to learn how to use WM.

  Of course both of those objections could be overcome with a specific sort of work, showing how to represent the desired algorithm in bayes nets.

  As for GD:

  • My back of the envelope calculation suggests that GPT-3 has trained on 7 orders of magnitude more data than a 10yo has experienced in their lifetime. Of course a different NN architecture (+ different task, different loss functions, etc) could just be that much more efficient than transformers; but overall, this doesn’t look good for the human-GD hypothesis.

    • Maybe your intention is to argue that we use GD with a really good prior, though! This seems much harder to dismiss.

  • Where does the gradient come from? Providing a gradient is a difficult problem which requires intelligence.

    • Even if the raw loss(/​reward) function is simple and fixed, it’s difficult to turn that into a gradient for learning, because you don’t know how to attribute punishment/​loss to specific outputs (actions or cognitive acts). The dumb method, policy-gradient, is highly data inefficient due to attributing reward/​punishment to all recent actions (frequently providing spurious gradients which adjust weights up/​down noisily).

    • But, quite possibly, the raw loss/​reward function is not simple/​fixed, but rather, requires significant inference itself. An example of this is imprinting.

  The last two sub-points only argue “against GD” in so far as you mean to suggest that the brain “just uses GD” (where “just” is doing a lot of work). My claim there is that more learning principles are needed (for example, model-based learning) to understand what’s going on.

  Indeed. Your crux is my question and my crux is your question. (My crux was: Does the brain, at the low level, use something more or less equivalent to the stuff modern NN’s do at a low level? From this I hoped to decide whether human-brain-sized networks could have human-level efficiency)

  Since the brain is difficult to pin down but ML experiments are not, I would think the more natural direction of inference would be to check the scaling laws and see whether it’s plausible that the brain is within the same regime.

• abramdemski 26 Apr 2021 15:05 UTC

  LW: 10 AF: 9

  AF

  in reply to: adamShimi’s comment on: Gra­da­tions of In­ner Align­ment Obstacles

  I guess the crux here is how much deceptiveness do you need before the training method is hijacked. My intuition is that you need to be relatively competent at deceptiveness, because the standard argument for why let’s say SGD will make good deceptive models more deceptive is that making them less deceptive would mean bigger loss and so it pushes towards more deception.

  I agree, but note that different methods will differ in this respect. The point is that you have to account for this question when making a basin of attraction argument.