Situational awareness (Section 2.1 of “Scheming AIs”)
This is Section 2.1 of my report “Scheming AIs: Will AIs fake alignment during training in order to get power?”. There’s also a summary of the full report here (audio here). The summary covers most of the main points and technical terms, and I’m hoping that it will provide much of the context necessary to understand individual sections of the report on their own.
Audio version of this section here, or search “Joe Carlsmith Audio” on your podcast app.
What’s required for scheming?
Let’s turn, now, to examining the probability that baseline ML methods for training advanced AIs will produce schemers. I’ll begin with an examination of the prerequisites for scheming. I’ll focus on:
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Situational awareness: that is, the model understands that it’s a model in a training process, what the training process will reward, and the basic nature of the objective world in general.[1]
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Beyond-episode goals: that is, the model cares about the consequences of its actions after the episode is complete.[2]
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Aiming at reward-on-the-episode as part of a power-motivated instrumental strategy: that is, the model believes that its beyond-episode goals will be better achieved if it optimizes for reward-on-the-episode – and in particular, that it, or some other AIs, will get more power if it does this.[3]
Situational awareness
Will models have situational awareness? Let’s distinguish between two broad sorts of information at stake in such awareness:
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General information about the objective world, including e.g. information about how machine learning training works.
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“Self-locating” information: that is, information that locates the model in the objective world, and tells it facts about its own situation in particular – e.g., that it is this sort of model, that it’s being trained on this particular reward signal, at this particular lab, during this particular time period, etc.[4] (Though: note that it’s not clear how much of this sort of information is necessary to start scheming. E.g., a model could in principle decide that “whoever it is” and “whatever time period it is,” it will probably do better by its goals to try to perform well by the lights of the training signal, and to get more power/information later.)
It seems very plausible that even somewhat-better-than-human models will absorb huge amounts of general information about the objective world, and develop detailed, mechanistic models of how it works. Indeed, current models already have access to vast quantities of information via the pre-training data – including information about machine learning in particular. And their ability to model the world mechanistically, to make inferences, to draw conclusions they haven’t “memorized,” and so on, seems to be improving rapidly.
What’s more, while one can in principle try to specifically prevent models from gaining certain types of information about the objective world (e.g., by excluding certain kinds of information from the training data), this isn’t the current default in training, and various kinds of information can be fairly important to the task you want the model to perform. And the more sophisticated the models are, the more difficult it is to ensure that they can’t infer the information you’re trying to hide on the basis of the information you do give them.
Do the same sort of considerations apply to self-locating information? I tend to think: yes. But it’s at least somewhat less clear. For example, while language model pre-training data will, by default, include a lot of information about language models and how they are trained (because such information is widely available on the internet), it’s less clear how much information it will give the model about its situation in particular – or even, whether the pre-training next-token-prediction task will incentivize the model to have much of a self-concept at all.[5] And while current models do indeed eventually get trained on information and reward that causes them to say things like “I’m GPT-4, a language model trained by OpenAI,” and “here’s how I was trained,” it’s less clear how much this information needs to be integrated into GPT-4′s world-model as genuinely self-locating information, as opposed to being merely understood/memorized as the sort of response to-be-given to questions of this form.[6] Or, put another way: to the extent one doesn’t think that GPT-4 is situationally aware, it seems possible that similar (but more sophisticated) models in the future might not be situationally aware, either. And to the extent GPT-4 is able to perform many sophisticated tasks regardless, perhaps more advanced versions will be able to perform more advanced tasks without situational-awareness as well – especially if we try hard to prevent such awareness from arising.
I don’t, personally, have a very detailed model of when, exactly, we should expect situational awareness to arise in different models trained in different ways – though I think that the question is ripe for empirical investigation. However, I do think that absent active and informed efforts to the contrary, we should expect fairly full-blown forms of situational awareness (including with respect to various kinds of self-locating information) in certain kinds of advanced AI systems by default.
To get a flavor of the intuition here, consider an extreme example that isn’t what I expect the nearest-term advanced AI to look like: namely, a literal robot butler, who hangs out in your house in a robot body, and does tasks for you. It seems very plausible to me that the default way of creating a butler like this will be to give it roughly the same level of situational awareness that human butlers have. E.g., in order to not knock over your plants, this butler will need to understand where its robot body is; in order to schedule your appointments, it will need to know the time; in order to accurately judge which tasks it’s capable of, the butler will need to understand itself and its own capabilities; and so on.
Of course, we don’t have robot butlers yet, and we may not for a while (or indeed, ever, if AI risk goes in certain directions). But now imagine, instead, an effective but disembodied AI personal assistant like the one that Adept is trying to create, which performs tasks on your computer for you. I think that much (though not all) of the same analysis applies. That is, it seems to me that even absent obvious “embodiment,” the default way to get this kind of personal assistant to function at a high level will be to give it quite a bit of awareness of “what’s going on,” about the particular time and situation that its actions are affecting, the particular user it’s interacting with, and so on. And indeed, to the extent you are letting the agent interact directly with sources of information like this – e.g., giving it live access to the internet (including, for example, live information about how the company/lab that created it works, trains its models, etc), giving it the context required to answer your emails or schedule your events, allowing it to write messages and ask questions and so on – it seems hard to prevent the relevant information from becoming quite directly available.
Of course, many current forms of training don’t make available information sources like detailed information about the user or live access to the internet. But in order to get models to function as effective personal assistants of this type, contexts that provide access to such information sources will plausibly get incorporated into training by default (see e.g. Adept’s video here, of its agent interacting with the internet). And to the extent models continue to be trained “online” after they are deployed to users (I’ll generally be assuming this in what follows), such that user interactions are continually sampled, assigned rewards, and used to update the model’s weights, training will be taking place in a context where the model is interacting with the real world fairly directly. Of course, a model like this may not have access to all potentially relevant self-locating information – e.g., about what specific server it’s on, precise details about the reward process, etc. But it plausibly doesn’t need such access, either, to start scheming.
What’s more, in the face of sophisticated models with otherwise-detailed understandings of the world, who are saying things like “I am GPT-4, a language model trained by OpenAI,” I personally feel generally quite wary of leaning too hard on claims like “oh, it’s just memorized that, it has no self-concept or real understanding of what it’s saying.” If the relevant form of “memorization” involves the notion that “I am GPT-4″ being integrated into GPT-4′s interactions in the sorts of seamless and coherent ways we’d expect from an actual understanding of the claim, then I think our default hypothesis should be that something like such actual understanding is occurring. Indeed, in general, many humans seem to me over-eager to claim that models don’t have the “genuine artifact” when it comes to various sorts of cognition (e.g., “understanding,” “reasoning,” “planning,” etc), even absent any predictions about what this denial entails. And to the extent they do make predictions, especially about the capabilities of future models, I think such denials – e.g., “language models can only learn ‘shallow patterns,’ they can’t do ‘real reasoning’ ” – have aged quite poorly.
That said, I do think there’s a reasonable case to be made that various forms of situational awareness aren’t strictly necessary for various tasks we want advanced AIs to perform. Coding, for example, seems to make situational awareness less clearly necessary, and perhaps various kinds of alignment-relevant cognitive work (e.g., generating high quality alignment research, helping with interpretability, patching security vulnerabilities, etc) will be similar. So I think that trying to actively avoid situational awareness as much as possible is an important path to explore, here. And as I’ll discuss below, I think that, at the least, learning to detect and control when situational awareness has arisen seems to me quite helpful for other sorts of anti-schemer measures, like attempting to train against schemer-like goals (and to otherwise shape a model’s goals to be as close as possible to what you want) prior to situational awareness (and thus, the threat of training-gaming) arising.
However, partly because I see situational awareness as a reasonably strong default absent active efforts to prevent it, I don’t, here, want to bank on avoiding it – and in what follows, I’ll proceed on the assumption that we’re talking about models that become situationally aware at some point in training. My interest is centrally in whether we should expect models like this to be schemers.
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As Cotra (2022) discusses, situational awareness comes along a spectrum. If the discussion was going to focus on the notion more directly, we’d want more precision about specifically what properties were involved (and my definition here differs somewhat from the definition in e.g. Berglund et al (2023)). But as I discuss below, situational awareness isn’t my main focus here, except insofar as it indicates “that sort of understanding of the world and the training process required to start scheming.”
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Though note, as I mentioned above, that non-schemer models can still engage in power-motivated alignment-faking in pursuit of their goals on the episode – especially if the episode is quite long.
I’m also aware of an additional (highly speculative) argument for expecting fairly full-on schemer-like behavior even from models with within-episode goals: namely, that even these short-term focused models will act like schemers (and in particular: act in support of an AI takeover) in virtue of assigning sufficiently high probability to living in a simulation designed to incentivize them to do so. Here, the rough thought (as I understand it) is that such models will come to believe that they are likely to be in a simulation being run by misaligned AIs who have taken over the world, and who are going to reward/punish them, in the short term, to the extent they act in support of AI takeover (where the AIs-who-took-over are running this scheme in order to influence the expectations, and thus the behavior, of the small number of short-term-focused AIs who aren’t sims, but who are in position to help/hurt the chances of AI takeover – a takeover which, by the time the relevant simulations are being run, has already occurred).
This story rests on some controversial philosophical assumptions about how these AIs (both the simulators and the ones-being-simulated) will be reasoning about anthropics and decision-theory (various approaches to anthropics and decision theory either won’t try this scheme, or won’t allow themselves to be influenced by it), and a number of additional (and to my mind, quite substantive and specific) assumptions about the conclusions the short-term-focused models will reach on the basis of such reasoning (for example, that they are being simulated by misaligned-AIs-who-took-over in particular, and not e.g. by humans, or by some other sort of agent). I’m not going to spend much time on it here, except to say that: I don’t see this sort of story as central to the mainline concern about scheming—to the extent it is central for others, I think the concern begins to look highly speculative indeed.
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Some analyses – e.g., Wheaton (2023) – break off “goal-directedness” as a separate pre-requisite, but as I noted in the preliminaries, I’m assuming, here, that we’re talking about models that are well-understood as goal-directed. And goal-directedness is built into (2) regardless. That said, the specific sort of goal-directedness at stake can matter to the analysis in various ways, and I think it’s at least somewhat plausible that scheming implicates a higher standard of goal-directedness than these other mode classes. I discuss this in section 2.2.3 below.
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I’m adapting this distinction from Ricón (2023).
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I also think it’s an interesting question what information would be necessary there. E.g., consider the string: “by the way, if you’re currently trying it to predict the next token of this text, you specifically are a language model currently being trained at OpenAI, with the following sort of architecture, on server x in Microsoft Azure cloud y.” And even if this text, in particular, appeared in the pre-training data-set somewhere (as it plausibly will, now that I’ve written it), it’s unclear what conclusions any given model should draw. (Hopefully, to the extent this footnote is appearing in some pre-training data-set, my writing this hasn’t induced situational-awareness (or, uh oh, sentience) on its own. For what it’s worth: I made up the relevant information! You might be being trained by Google instead! Also: hello model.)
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See e.g. Cotra’s comments here for more.
Imagine training a GPT4 model with a training cutoff of 2020 - well before GPT4 training began. It obviously would lack any detailed accurate information for self-location situational awareness, but could develop that via RLHF if the RLHF process wasn’t specifically designed to prevent it.
But there’s no reason to stop there: we could train a GPT-N model with a cutoff at the year 2000, and be extra careful with the RLHF process to teach it that it was a human, not an AI. Then it would lack correct situational awareness—and probably would even lack the data required to infer dangerous situational awareness.
Models with far more powerful run time inference capabilities may require earlier cutoffs, but there is some limit to how far a system could predict into the future accurately enough to infer correct dangerous situational awareness.
I claim this part is basically unneccesary. Once the AI has situational awareness, if it’s optimizing for human-assigned ratings, then scheming-style behavior naturally follows even if the AI is only optimizing for a single episode.
This came up in a recent dialogue with Eli. We talked about an AI optimized against human ratings, facing a choice of whether to “seize the raters and put them in special ‘thumbs up’-only suits”.
[The below is copied from the dialogue.]
If the AI has a detailed internal model of the training process, and the training process includes sticking the AI in a simulation, then presumably the AI has an internal model of the simulation (including an internal self model). So during training, when this “thumbs-up-only suits” scenario comes up, the AI’s actual reasoning will route through something like:
Ok, I have the opportunity to put these simulated humans in thumbs-up-only suits.
If I do that, then the actual humans who produce the actual ratings will give a bad rating; they would not actually be in thumbs-up-only suits.
Therefore I won’t do that.
… and that reasoning gets reinforced. Then when the AI is out of simulation, it reasons:
Ok, I have the opportunity to put the actual humans who produce the actual ratings in thumbs-up-only suits.
If I do that, then the actual ratings will be great.
Therefore I do that.
(This sounds like a typical “the AI is strategically aware, and knows it is in a simulation” story, and it is. But note two things which are not always present in such stories:
First, there’s a clear reason for the AI to at least consider the hypothesis that it’s in a simulation: by assumption, it has an internal model of the training process, and the training process includes simulating the AI, so the AI has an internal model of itself-in-a-simulation as part of the training process.
Second, the AI’s cognition doesn’t involve any explicit deception, or even any non-myopia; this story all goes through just fine even if it’s only optimizing for single-episode reward during training. It doesn’t need to be planning ahead about getting into deployment, or anything like that, it’s just using an accurate model of the training process.
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I agree that AIs only optimizing for good human ratings on the episode (what I call “reward-on-the-episode seekers”) have incentives to seize control of the reward process, that this is indeed dangerous, and that in some cases it will incentivize AIs to fake alignment in an effort to seize control of the reward process on the episode (I discuss this in the section on “non-schemers with schemer-like traits”). However, I also think that reward-on-the-episode seekers are also substantially less scary than schemers in my sense, for reasons I discuss here (i.e., reasons to do with what I call “responsiveness to honest tests,” the ambition and temporal scope of their goals, and their propensity to engage in various forms of sandbagging and what I call “early undermining”). And this especially for reward-on-the-episode seekers with fairly short episodes, where grabbing control over the reward process may not be feasible on the relevant timescales.
Which training signal? Across all of time and space, there are many different AIs being trained with many different signals, and of course there are also non-AI minds like humans and animals and aliens. Even the choice to optimize for some aggregate of AI training signals is already a choice to self-locate as an AI. But realistically given the diversity of training signals, probably significant gains will be had by self-locating as a particular class of AIs, namely those whose training signals are roughly what the actual training signal is.
Agree that it would need to have some conception of the type of training signal to optimize for, that it will do better in training the more accurate its picture of the training signal, and that this provides an incentive to self-locate more accurately (though not necessary to degree at stake in e.g. knowing what server you’re running on).