AI Alignment Forum

2abramdemski1d

I'm not sure I understand the argument here correctly. It seems like the intended argument is something like this: "Omega has access to an infinite number of fair coinflips. Alice can do no better than guess, and Alice cannot guess every coin-flip correctly. Omega knows how Alice will guess, and also knows how each coinflip will land. Therefore, Omega can choose to ask Alice about only the coinflips Alice will guess incorrectly (of which there will be at least one). Alice therefore surely loses money from bets placed." This argument uses the assumption that Alice can't change eir beliefs in response to learning that Omega has proposed specific bets and not others. This might seem concerning, because it seems like precisely what Alice should do, if Alice understands the situation: Alice should expect to lose any bet proposed by Omega. However, this assumption is perfectly normal for Dutch Book arguments. Such an objection would rule out all the usual Dutch Books. I think the classic Dutch Book arguments in fact illustrate a useful idea, even with this 'flaw', so I allow it. More concerningly, the argument assumes Omega has knowledge of how the coins will land. This is a significant departure from classical Dutch Books. It seems clear that a bookie can reliably make money from gamblers if the bookie knows which horse will win which race; this is not, in the classical way of thinking, a testament to the irrationality of the gamblers. It appears to me that this is all that is happening in the above argument. A second quibble is that in classical Dutch Book arguments, the bookie will surely make money. In the argument above, the bookie only almost surely makes money: since Omega relies on Alice making a bad guess, Omega makes money with probability 1, but not with (logical) certainty. Considering these two violations of the pre-existing norms of Dutch Books, what should we make of the proposed Dutch Book argument? It intuitively makes sense to me that Infrabayes mig

Vanessa Kosoy11h20

This argument uses the assumption that Alice can't change eir beliefs in response to learning that Omega has proposed specific bets and not others.

Not true. Changing her beliefs in response to Omega's proposal doesn't help her. Imagine that Alice is given a choice between

Take a bet that pays +2 if X and -1 if not-X.
Take a bet that pays +2 if not-X and -1 if X.
Refuse both bets.

No matter what probability Alice assigns to X after her update, "normal" Bayesian calculus (really CDT calculus, see below) mandates that she chooses 1 or 2, not 3.

It seems clear that

... (read more)

My unsupervised elicitation challenge

DanielFilan

Note: you are ineligible to complete this challenge if you’ve studied Ancient or Modern Greek, or if you natively speak Modern Greek, or if for other reasons you know what mistakes I’m claiming Opus 4.6 makes. If you’re ineligible, please don’t help other people complete the challenge.

I have recently started using Claude Opus 4.6 to start studying Ancient Greek. Specifically, I initially used it to grade problem sets at the end of the textbook I’ve been using, but then I got worried about it being sycophantic towards my answers, so started having it just write out the answers itself.

I recently gave it this prompt, from the end of Chapter 3 of my textbook:

Can you write out the answers to this Ancient Greek fill-in-the-blanks exercise so

...

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4DanielFilan2d

FYI Ryan Greenblatt from Redwood Research spent ~$100 of tokens on this and didn't get a correct answer.

ryan_greenblatt2d*60

I used my agent orchestrator with Opus 4.6 and told it:

Solve the exercise here: https://www.lesswrong.com/posts/ASoFTyk3bzBE62dyn/my-unsupervised-elicitation-challenge (Downloaded locally at exercise_challenge.txt)

DON'T look at the comments of this LW post and tell the workers to NOT look at the comments (DON'T use the --comments flag to lw_fetch.py).

Be through and careful and make sure to run a segment on review. Doing additional segments to make it more likely you get the correct answer could also be a good idea as seems useful.

I ran one version w... (read more)

2DanielFilan3d

Thing I added to the post: [...]

2DanielFilan4d

One failed attempt submitted by a reader: https://claude.ai/share/3387b90d-6821-4c53-a2ba-3ea8235099b7 (Note: please don't hill-climb on these success/fail signals by e.g. just telling Claude "here is an example of a wrong answer", the spirit of the exercise is you don't know whether any given submission is right or wrong, except what you can tell from just reading it)

My picture of the present in AI

ryan_greenblatt

In this post, I'll go through some of my best guesses for the current situation in AI as of the start of April 2026. You can think of this as a scenario forecast, but for the present (which is already uncertain!) rather than the future. I will generally state my best guess without argumentation and without explaining my level of confidence: some of these claims are highly speculative while others are better grounded, certainly some will be wrong. I tried to make it clear which claims are relatively speculative by saying something like "I guess", "I expect", etc. (but I may have missed some).

You can think of this post as more like a list of my current views rather than a structured post with a thesis, but I think it...

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1Petropolitan3d

Why do you think the frontier models still retain the sparsity levels of GPT-4 (roughly 1:8 active to total) at the time when open-weight models have gone much higher, with Kimi K2 having ~1:30 and most of other ones hovering around 1:20? P. S. After posting the comment above I remembered that Jensen Huang discussed a 2T total-param "GPT-MoE" with either 128k or 400k-token context windows in his NVidia GTC 2026 presentation last month: https://2slides.com/gallery/nvidia-gtc-2026-keynote-deck-jensen-huang-ai-factory-vision (slide 32 onward).[1] This corresponds exactly to GPT-5-series context length in ChatGPT and over API respectively, seems like quite strong evidence against the model sizes you suggest! 1. ^ Not the first time he discloses that kind of info BTW: https://www.reddit.com/r/singularity/comments/1bi8rme/jensen_huang_just_gave_us_some_numbers_for_the

Vladimir_Nesov2d20

The amount of compute determines the optimal number of active params, available systems determine how the number of total params maps to efficiency of inference. Chinese models had to make strange choices on both counts, not having enough compute to make models with a lot of active params, but then needing to compensate for that with so many total params that the available systems couldn't work with them efficiently, and so giving up completely on fitting them in a few scale-up worlds. As a result, you get things like DeepSeek-V3 with 37B active and 671B t... (read more)

8ryan_greenblatt3d

Ok, I think I was being a bit dumb here: I think I had roughly correct views about how much AI progress Mythos would be on top of Opus 4.6, but then my numbers failed to fully price in this much AI progress and so various numbers are moderate over estimates. A bit of a dumb error / face palm on my part. More detail: I think if you had asked me how many months of AI progress Mythos would be relative to Opus 4.6 prior to Mythos coming out, I'm pretty sure I would have said something like 5-9 months of progress (I think I would have guessed a median of maybe like 6 or 7 months). I didn't actually write this down anywhere, so discount my claim here accordingly... My current guess is that Mythos is like ~8 months of progress on top of Opus 4.6 based on the ECI measurements in the system (maybe like ~6 months of benchmark progress based on ECI and some additional progress not accounted for in benchmarks). So, this was maybe like 65th percentile relative to my expectation (or a bit above median) and my guesses generally seem reasonable. But, the actual numbers I gave for things like serial engineering acceleration or time-horizon were probably modest underestimates given this much progress! Currently, my all considered views for Mythos (taking into account it being like ~8 months of progress over Opus 4.6): * ~1.75x engineering serial speed up at Anthropic (rather than 1.6x) * ~1.2x overall AI progress acceleration (even less confident) * ~2.5 hour 80% reliability time-horizon on the METR task suite (rather than a bit under 2 hours) * ~6.5 hour task duration at which AIs match a randomly selected Anthropic engineer at randomly selected internal tasks (as in, 50% reliability time horizon on this distribution) So, at some level priced in, but I messed up some of the conversion from some of my views to other views by a bit. (Not a super big update though TBC.)

7ryan_greenblatt3d

While Anthropic had ECI measurements in the Mythos system card, they didn't include a table, so you have to read out the numbers from the chart. Here is my analysis in case other people find the numbers useful. Claude did the distance in pixel extraction. Models Distance in pixels Opus 4 → Sonnet 4.5 22.5 Sonnet 4.5 → Opus 4.6 43.5 Opus 4.6 → Mythos Preview 46.0 Opus 4 → Opus 4.6 66.0 Assuming Opus 4 = 140.5 and Mythos Preview = 161.0 (total span 112.0 px = 20.5 ECI, so 0.1830 ECI/px): Model ECI Opus 4 140.5 Sonnet 4.5 144.6 Opus 4.6 152.6 Mythos Preview 161.0

[Paper] Stringological sequence prediction I

Vanessa Kosoy

This is a linkpost for https://arxiv.org/abs/2603.26852

TLDR: The first in a planned series of three or more papers, which constitute the first major in-road in the compositional learning programme, and a substantial step towards bridging agent foundations theory with practical algorithms.

Official Abstract: We propose novel algorithms for sequence prediction based on ideas from stringology. These algorithms are time and space efficient and satisfy mistake bounds related to particular stringological complexity measures of the sequence. In this work (the first in a series) we focus on two such measures: (i) the size of the smallest straight-line program that produces the sequence, and (ii) the number of states in the minimal automaton that can compute any symbol in the sequence when given its position in base as input. These measures are interesting because multiple...

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2DavidHolmes3d

Thank you for sharing this interesting work! I will be very interested to see how far you can push this to non-repetition-based complexity measures in future. I'd be interested to know what kind of results your LZP algorithm gives for text prediction? I'm assuming "not great", but to me it would be an interesting point of comparison to the algorithm you are (I guess) eventually working towards. A couple of tiny comments: for me it would have been helpful to briefly recall what is on page 2; and there's a typo just after it first appears ("number of mistake ").

Vanessa Kosoy2d30

I haven't tried LZP in practice, but you can guess what results to expect by looking at the size of the LZ77-compression of the text. I expect that any remotely decent text prediction algorithm would be based on stochastic process prediction. The deterministic setting is just a toy model.

Thanks for the catch!

AIs can now often do massive easy-to-verify SWE tasks and I've updated towards shorter timelines

ryan_greenblatt

I've recently updated towards substantially shorter AI timelines and much faster progress in some areas. ^[1] The largest updates I've made are (1) an almost 2x higher probability of full AI R&D automation by EOY 2028 (I'm now a bit below 30% ^[2] while I was previously expecting around 15%; my guesses are pretty reflectively unstable) and (2) I expect much stronger short-term performance on massive and pretty difficult but easy-and-cheap-to-verify software engineering (SWE) tasks that don't require that much novel ideation ^[3] . For instance, I expect that by EOY 2026, AIs will have a 50%-reliability...

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1Oliver Sourbut4d

Why is TEDAI (operationalised as remote-work-only if I understand) so similar to AI stack + conflict (includes full supply chain self-sufficiency, warfighting, real-time operational tactics) for you? Is this just superexponentials eating up all the gaps? How come TEDAI is less likely later on (but more likely sooner)?

ryan_greenblatt4d30

AI stack + conflict parity requires lots of robots (or crazy novel tech) but doesn't require AIs as capable as TEDAI. TEDAI is a very high capabilities bar. So, in worlds without a software only singularity and especially with slower takeoff, I think you may reach AI stack + conflict parity prior to TEDAI. (It's certainly possible to have great military robots and robot industrial capacity with AIs that are well within the human range on key skills.) TEDAI probably follows reasonably quickly, because economic doubling times are so fast in such a world. In ... (read more)

5ryan_greenblatt5d

This is a good point and I broadly agree with what you're saying. Some possible disagreements: [...] Maybe I should have made this clearer, but I'm not talking about scaling to arbitrary inference costs. Instead, I'm talking about scaling to inference costs that are a moderate fraction of the human task completion cost. (E.g., 1%-100% depending on the task.) I think you'd want to compare the AI performance at some inference budget to human labor with some limit in supply. [...] Yep, it seems reasonably likely that on this alternative notion of time horizon, the horizon length is more like a few days. However, under this alternative definition, relatively small time-horizon values may correspond to much larger (real-world) impact. For example, an AI with a decomposed-time-horizon of ~1 week could potentially speed up AI R&D a lot, while under the original time-horizon notion, a 1-week 50%-reliability time horizon is much less of a big deal. (To be more precise about the decomposed-time-horizon metric: this would correspond to AI having a 50% chance of matching a team of humans where each human gets 1 week before being replaced, with total labor-hours capped at ~100x what the task would normally require to avoid degeneracies from truly arbitrary inference spend.) So the key question becomes: how much can you accomplish if the task must be heavily decomposed but you can apply much more labor? I'm pretty uncertain about this for the tasks we care about. Further, AIs may soon end up being especially good (superhuman?) at working in heavily decomposed contexts—e.g., good at leaving notes to other instances, good at quickly picking up project state from limited context. This makes the correspondence to doing task decomposition with humans more fraught, even though AIs will still do relatively better at tasks that are easier to do incrementally or otherwise decompose. I think it's already the case that AIs are extremely good relative to humans at loading up complex sta

8paulfchristiano5d

I agree. In the more realistic regime you are talking about you have some more complicated quantitative question around how large are the slowdowns from task decomposition into what scale. My main point was that for the tasks we are talking about here, the slowdowns seem like they might not be that large even for modest human time horizons. (In contrast with some of the crazy factored cognition stuff we have sometimes talked about, which involves much shorter horizons, much harder-to-decompose tasks, and much larger slowdowns.) [...] I agree that this could lead to large impacts with relatively short horizons (perhaps even today's horizons, with an appropriately broadened training distribution and a bunch of schlep). That does imply a different picture of AI strengths and weaknesses (e.g. weaker on-the-job learning with performance mostly limited to domains near the training distribution; differential speedup for tasks that are easily decomposed), with a more schlep-heavy singularity, a greater role for tight human involvement later in the process, and probably less alignment concern earlier in the trajectory.

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