All of TurnTrout's Comments + Replies

On applying generalization bounds to AI alignment. In January, Buck gave a talk for the Winter MLAB. He argued that we know how to train AIs which answer on-distribution questions at least as well as the labeller does. I was skeptical. IIRC, his argument had the following structure:

Premises:

1. We are labelling according to some function f and loss function L.

2. We train the network on datapoints (x, f(x)) ~ D_train.

3. Learning theory results give (f, L)-bounds on D_train. 

Conclusions:

4. The network should match f's labels on the rest of D_train, on av

Thoughts on "Deep Learning is Robust to Massive Label Noise."

We show that deep neural networks are capable of generalizing from training data for which true labels are massively outnumbered by incorrect labels. We demonstrate remarkably high test performance after training on corrupted data from MNIST, CIFAR, and ImageNet. For example, on MNIST we obtain test accuracy above 90 percent even after each clean training example has been diluted with 100 randomly-labeled examples. Such behavior holds across multiple patterns of label noise, even when erroneous l

Thoughts on "The Curse of Recursion: Training on Generated Data Makes Models Forget." I think this asks an important question about data scaling requirements: what happens if we use model-generated data to train other models? This should inform timelines and capability projections.

Abstract:

Stable Diffusion revolutionised image creation from descriptive text. GPT-2, GPT-3(.5) and GPT-4 demonstrated astonishing performance across a variety of language tasks. ChatGPT introduced such language models to the general public. It is now clear that large language mo

Probably not, but mostly because you phrased it as inductive biases to be washed away in the limit, or using gimmicks like early stopping.

LLMs aren't trained to convergence because that's not compute-efficient, so early stopping seems like the relevant baseline. No?

everyone who reads those seems to be even more confused after reading them

I want to defend "Reward is not the optimization target" a bit, while also mourning its apparent lack of clarity. The above is a valid impression, but I don't think it's true. For some reason, some people really get a lot ... (read more)

I agree that with time, we might be able to understand. (I meant to communicate that via "might still be incomprehensible")

All the models must converge on the same optimal solution for a deterministic perfect-information game like Othello and become value-equivalent, ignoring the full board state which is irrelevant to reward-maximizing.

Strong claim! I'm skeptical (EDIT: if you mean "in the limit" to apply to practically relevant systems we build in the future. If so,) do you have a citation for DRL convergence results relative to this level of expressivity, and reasoning for why realistic early stopping in practice doesn't matter? (Also, of course, even one single optimal ... (read more)

AI cognition doesn't have to use alien concepts to be uninterpretable. We've never fully interpreted human cognition, either, and we know that our introspectively accessible reasoning uses human-understandable concepts.

Just because your thoughts are built using your own concepts, does not mean your concepts can describe how your thoughts are computed. 

Or:

The existence of a natural-language description of a thought (like "I want ice cream") doesn't mean that your brain computed that thought in a way which can be compactly described by familiar concepts... (read more)

I agree that there's something nice about activation steering not optimizing the network relative to some other black-box feedback metric. (I, personally, feel less concerned by e.g. finetuning against some kind of feedback source; the bullet feels less jawbreaking to me, but maybe this isn't a crux.)

(Medium confidence) FWIW, RLHF'd models (specifically, the LLAMA-2-chat series) seem substantially easier to activation-steer than do their base counterparts. 

Offline RL can work well even with wrong reward labels. I think alignment discourse over-focuses on "reward specification." I think reward specification is important, but far from the full story. 

To this end, a new paper (Survival Instinct in Offline Reinforcement Learning) supports Reward is not the optimization target and associated points that reward is a chisel which shapes circuits inside of the network, and that one should fully consider the range of sources of parameter updates (not just those provided by a reward signal). 

Some relevant qu... (read more)

Delicious food does seem like a good (but IMO weak) point in favor of reward-optimization, and pushes up my P(AI cares a lot about reward terminally) a tiny bit. But also note that lots of people (including myself) don't care very much about delicious food, and it seems like the vast majority of people don't make their lives primarily about delicious food or other tight correlates of their sensory pleasure circuits. 

If pressing a button is easy and doesn't conflict with taking out the trash and doing other things it wants to do, it might try it.

This i... (read more)

What is "shard theory"? I've written a lot about shard theory. I largely stand by these models and think they're good and useful. Unfortunately, lots of people seem to be confused about what shard theory is. Is it a "theory"? Is it a "frame"? Is it "a huge bag of alignment takes which almost no one wholly believes except, perhaps, Quintin Pope and Alex Turner"?

I think this understandable confusion happened because my writing didn't distinguish between: 

1. Shard theory itself, 
   1. IE the mechanistic assumptions about internal motivational structure, whic

Consider what update equations have to say about "training game" scenarios. In PPO, the optimization objective is proportional to the advantage given a policy $\pi$, reward function $R$, and on-policy value function $v^{\pi }$:

Consider a mesa-optimizer acting to optimize some mesa objective. The mesa-optimizer understands that it will be updated proportional to the advantage. If the mesa-optimizer maximizes reward, this corresponds to maximizing the intensity of the gradients it receives, thus maximally updatin... (read more)

An Arxiv version is forthcoming. We're working with Gavin Leech to publish these results as a conference paper. 

I'm also excited by tactics like "fully reverse engineer the important bits of a toy model, and then consider what tactics and approaches would -- in hindsight -- have quickly led you to understand the important bits of the model's decision-making."

I still don't follow. Apparently, TL's center_writing_weights is adapting the writing weights in a pre-LN-invariant fashion (and also in a way which doesn't affect the softmax probabilities after unembed). This means the actual computations of the forward pass are left unaffected by this weight modification, up to precision limitations, right? So that means that our results in particular should not be affected by TL vs HF. 

We used TL to cache activations for all experiments, but are considering moving away to improve memory efficiency. 

TL removes the mean from all additions to the residual stream which I would have guessed that this would solve the problem here.

Oh, somehow I'm not familiar with this. Is this center_unembed? Or are you talking about something else?

Do you have evidence for this?

Yes, but I think the evidence didn't actually come from the "Love" - "Hate" prompt pair. Early in testing we found paired activation additions worked better. I don't have a citeabl... (read more)

Yeah, seems tough to avoid "reward" in that situation. Thanks for pointing this out.

I'm currently excited about a "macro-interpretability" paradigm. To quote Joseph Bloom:

TLDR: Documenting existing circuits is good but explaining what relationship circuits have to each other within the model, such as by understanding how the model allocated limited resources such as residual stream and weights between different learnable circuit seems important. 

The general topic I think we are getting at is something like "circuit economics". The thing I'm trying to gesture at is that while circuits might deliver value in distinct ways (such as redu

Handling compute overhangs after a pause. 

Sometimes people object that pausing AI progress for e.g. 10 years would lead to a "compute overhang": At the end of the 10 years, compute will be cheaper and larger than at present-day. Accordingly, once AI progress is unpaused, labs will cheaply train models which are far larger and smarter than before the pause. We will not have had time to adapt to models of intermediate size and intelligence. Some people believe this is good reason to not pause AI progress.

There seem to be a range of relatively simple pol... (read more)

The advantage definition itself is correct and non-oscillating... Oscillating or nonconvergent value estimation is not the cause of policy mode collapse.

The advantage is (IIUC) defined with respect to a given policy, and so the advantage can oscillate and then cause mode collapse. I agree that a constant learning rate schedule is problematic, but note that ACTDE converges even with a constant learning rate schedule. So, I would indeed say that oscillating value estimation caused mode collapse in the toy example I gave?

Though note that ideally, once we actually know with confidence what is best, we should be near-greedy about it, rather than softmaxing!

I disagree. I don't view reward/reinforcement as indicating what is "best" (from our perspective), but as chiseling decision-making circuitry into the AI (which may then decide what is "best" from its perspective). One way of putting a related point: I think that we don't need to infinitely reinforce a line of reasoning in order to train an AI which reasons correctly. 

(I want to check -- does this response make sense to you? Happy to try explaining my intuition in another way.)

Is this identical to training the next-to-last layer to predict the rewards directly, and then just transforming those predictions to get a sample?

In the tabular case, that's equivalent given uniform ${\pi }_0$. Maybe it's also true in the function approximator PG regime, but that's a maybe -- depends on inductive biases. But often we want a pretrained ${\pi }_0$ (like when doing RLHF on LLMs), which isn't uniform.

RL creates agents, and RL seemed to be the way to AGI. In the 2010s, reinforcement learning was the dominant paradigm for those interested in AGI (e.g. OpenAI). RL lends naturally to creating agents that pursue rewards/utility/objectives. So there was reason to expect that agentic AI would be the first (and by the theoretical arguments, last) form that superintelligence would take.

Why are you confident that RL creates agents? Is it the non-stochasticity of optimal policies for almost all reward functions? The on-policy data collection of PPO? I think there... (read more)

I don't think we should call this "algebraic value editing" because it seems overly pretentious to say we're editing the model's values We don't even know what values are!

I phased out "algebraic value editing" for exactly that reason. Note that only the repository and prediction markets retain this name, and I'll probably rename the repo activation_additions.

Physiological events associated with pregnancy (mostly hormones) rewires the mother's brain such that when she gives birth, she immediately takes care of the young, grooms them etc., something she has never done before.

Salt-starved rats develop an appetite for salt and are drawn to stimuli predictive of extremely salty water

I've been wondering about the latter for a while. These two results are less strongly predicted by shard theoretic reasoning than by "hardcoded" hypotheses. Pure-RL+SL shard theory loses points on these two observations, and points to other mechanisms IMO (or I'm missing some implications of pure-RL+SL shard theory).

"There are theoretical results showing that many decision-making algorithms have power-seeking tendencies."

I think this is reasonable, although I might say "suggesting" instead of "showing." I think I might also be more cautious about further inferences which people might make from this -- like I think a bunch of the algorithms I proved things about are importantly unrealistic. But the sentence itself seems fine, at first pass.

This is awesome. As you have just shown, there are a ton of low-hanging activation additions just waiting to be found. Team shard has barely explored this large space of interventions. I encourage people to play around with activation additions more, via e.g. our demo colabs for GPT-2-XL (Colab Pro required) and GPT-2-small (Colab Pro not required). Though more sophisticated interventions (like the one you demonstrate) will require coding, and not just playing with our demo widget.

You looked at GPT-2-small. I injected your activation additions into GPT-2-X... (read more)