Precursor Detection, Classification and Assistance (PreDCA)

Infra-Bayesian physicalism provides us with two key building blocks:

• Given a hypothesis about the universe, we can tell which programs are running. (This is just the bridge transform.)

• Given a program, we can tell whether it is an agent, and if so, which utility function it has^[1] (the “evaluating agent” section of the article).

I will now outline how we can use these building blocks to solve both the inner and outer alignment problem. The rough idea is:

• For each hypothesis in the prior, check which agents are precursors of our agent according to this hypothesis.

• Among the precursors, check whether some are definitely neither humans nor animals nor previously created AIs.

• If there are precursors like that, discard the hypothesis (it is probably a malign simulation hypothesis).

• If there are no precursors like that, decide which of them are humans.

• Follow an aggregate of the utility functions of the human precursors (conditional on the given hypothesis).

Detection

How to identify agents which are our agent’s precursors? Let our agent be $G$ and let $H$ be another agents which exists in the universe according to hypothesis $\Theta$^[2]. Then, $H$ is considered to be a precursor of $G$ in universe $\Theta$ when there is some $H$-policy $\sigma$ s.t. applying the counterfactual ”$H$ follows $\sigma$” to $\Theta$ (in the usual infra-Bayesian sense) causes $G$ not to exist (i.e. its source code doesn’t run).

A possible complication is, what if $\Theta$ implies that $H$ creates $G$ /​ doesn’t interfere with the creation of $G$? In this case $H$ might conceptually be a precursor, but the definition would not detect it. It is possible that any such $\Theta$ would have a sufficiently large description complexity penalty that it doesn’t matter. On the second hand, if $\Theta$ is unconditionally Knightian uncertain about $H$ creating $G$ then the utility will be upper bounded by the scenario in which $G$ doesn’t exist, which is liable to make $\Theta$ an effectively falsified hypothesis. On the third hand, it seems plausible that the creation of $G$ by $H$ would be contingent on $G$’s behavior (Newcomb-style, which we know how it works in infra-Bayesianism), in which case $\Theta$ is not falsified and the detection works. In any case, there is a possible variant of the definition to avoid the problem: instead of examining only $\Theta$ we also examine coarsenings of $\Theta$ which are not much more complex to describe (in the hope that some such coarsening would leave the creation of $G$ uncertain).

Notice that any agent whose existence is contingent on $G$’s policy cannot be detected as a precursor: the corresponding program doesn’t even “run”, because we don’t apply a $G$-policy-counterfactual to the bridge transform.

Classification

How to decide which precursors are which? One tool we have is the $g$ parameter and the computational resource parameters in the definition of intelligence. In addition we might be able to create a very rough neuroscience-based model of humans. Also, we will hopefully have a lot of information about other AIs that can be relevant. Using these, it might be possible to create a rough benign/​malign/​irrelevant classifier, s.t.

• Humans are classified as “benign”.

• Most (by probability mass) malign simulation hypotheses contain at least one precursor classified as “malign”.

• Non-human agents that exist in the causal past of our AI in the null (non-simulation) hypothesis are classified as “irrelevant”.

Assistance

Once we detected and classified precursors in each hypothesis, we discard all hypotheses that contain malign precursors. In the remaining hypotheses, we perform some kind of aggregation on the utility functions of the benign precursors (for example, this). The utility functions from different hypotheses are somehow normalized to form the overall utility function. Alternatively, we do a maximal lottery vote for the policy, where each hypothesis is a voter with weight proportional to its prior probability mass.

Inner Alignment

Why can this solve inner alignment? In any model-based approach, the AI doesn’t train the policy directly. Instead, it trains models and uses them to compute the policy. I suspect that the second step cannot create mesa-optimizers, since it only involves control and not learning^[3]. Hence, any mesa-optimizer has to originate from the first step, i.e. from the model/​hypothesis. And, any plausible physicalist hypothesis which contains a mesa-optimizer has to look like a malign simulation hypothesis.

Outer Alignment

Why can this solve outer alignment? Presumably, we are aggregating human utility functions. This doesn’t assume humans are perfect agents: $g$ can be less than infinity. I suspect that when $g<\infty$ the utility function becomes somewhat ambiguous, but the ambiguity can probably be resolved arbitrarily or maybe via a risk-averse method. What if the AI modifies the humans? Then only pre-modification humans are detected as precursors, and there’s no problem.

Moreover, the entire method can be combined with the Hippocratic principle to avoid catastrophic mistakes out of ignorance (i.e. to go from intent alignment to impact alignment).

There’s a class of AI risk mitigation strategies which relies on the users to perform the pivotal act using tools created by AI (e.g. nanosystems). These strategies are especially appealing if we want to avoid human models. Here is a concrete alignment protocol for these strategies, closely related to AQD, which we call autocalibrating quantilized RL (AQRL).

First, suppose that we are able formulate the task as episodic RL with a formally specified reward function. The reward function is necessarily only a proxy for our true goal, since it doesn’t contain terms such as “oh btw don’t kill people while you’re building the nanosystem”. However, suppose the task is s.t. accomplishing it in the intended way (without Goodharting or causing catastrophic side effects) is easier than performing any attack. We will call this the “relative difficulty assumption” (RDA). Then, there exists a value for the quantilization parameter s.t. quantilized RL performs the task in the intended way.

We might not know how to set the quantilization parameter on our own, but we can define a performance goal for the task (in terms of expected total reward) s.t. the RDA holds. This leads to algorithms which gradually tune the quantilization parameter until the performance goal is met, while maintaining a proper balance between safety and sample complexity. Here it is important to keep track of epistemic vs. aleatoric uncertainty: the performance goal is the expectation of total reward relatively to aleatoric uncertainty (i.e. the stochasticity of a given hypothesis), whereas the safety goal is a bound on the expected cost of overshooting the optimal quantilization parameter relatively to both aleatoric and epistemic uncertainty (i.e. uncertainty between different hypotheses). This secures the system against malign hypotheses that are trying to cause an overshoot.

Notice the hardening the system (i.e. making it more secure using conventional methods) increases the likelihood of the RDA. That is, although it is infeasible to manually harden the system against superintelligent attacks, it can very well be feasible to harden it against attacks available at the minimal level of optimization power (= quantilization parameter) required to meet the performance goal, at least to such an extent that the intended solution becomes more appealing for the AI.

AQRL involves the risk that the RDA is false, even though it seems true to the designers. To mitigate this risk, we can deploy honeypots. That is, we add auxiliary goals to our reward function s.t. (i) if the goal is reached, maximal total reward is awarded (ii) the goal is harmless in itself (iii) reaching the goal is still harder than the intended solution, but by a smaller margin than performing attacks (iv) we can detect the event of reaching the goal. For example, suppose that the AI is not supposed to have Internet access, so gaining Internet access is a path to a variety of possible attacks. Then, we can add an auxiliary goal of the form “send such-and-such innocuous packet to such-and-such IP address”. If the RDA is false and the AI succeeds gaining Internet access earlier (on the quantilization parameter scale) than reaching the performance goal, once the AI sent the packet it will randomize all its remaining actions (since it is operating at the earliest quantilization parameter which allows this). The users will then be alerted that security was breached and rethink their next steps.

Now, suppose that we can only specify the reward function via concepts that have to be learned from examples. This opens the risk of generalization failure. Such risk is not necessarily a problem since we are still protected by quantilization. However, it needs to be factored into our safety bounds. An especially concerning possibility is that the AI will interpret the concepts as “would be labeled by humans as such-and-such” instead of the intended interpretation, creating incentives to deceive. Moreover, this encourages learning human models which puts more pressure on the RDA by making it easier to attack.

In order to avoid learning human models, we can use methods along these lines. Specifically, suppose that, in addition to the dataset for learning out task-relevant concepts, we supply a dataset designed specifically for learning human models. We can then design an algorithm that produces models of the task-relevant concepts s.t. the human-centric dataset cannot be compressed w.r.t. them. That is, the algorithm makes sure that access to the models it produces doesn’t help with learning the human-centric dataset, implying that the concept models don’t contain human models. Moreover, we can extend this approach to the entire process, s.t. human models are not learned from any other source of information as well.

Notice that although this method excludes human models from the actual RL process, it encourages them in intermediate computations, since we are actively supplying a human-centric dataset to the system. But, this is not dangerous if the intermediate computation is hardened against non-Cartesian daemons (a big “if” but one we need to deal with anyway).

I suspect you’re reacting to the actual beliefs (disbelief in your example), rather than the word usage. In common parlance, “skeptical” means “assign low probability”, and that usage is completely normal and understandable.

The ability to dismiss expertise you don’t like is built into humans, not a feature of the word “skeptical”. You could easily replace “I am skeptical” with “I don’t believe” or “I don’t think it’s likely” or just “it’s not really true”.

https://​​www.facebook.com/​​groups/​​1781724435404945 might be a good way to find somebody who provides that kind of service.

You could post a research bounty on this site.

basically every company eventually becomes a moral maze

Agreed, but Silicon Valley wisdom says founder-led and -controlled companies are exceptionally dynamic, which matters here because the company that deploys AGI is reasonably likely to be one of those. For such companies, the personality and ideological commitments of the founder(s) are likely more predictive of external behavior than properties of moral mazes.

Facebook’s pivot to the “metaverse”, for instance, likely could not have been executed by a moral maze. If we believed that Facebook /​ Meta was overwhelmingly likely to deploy one of the first AGIs, I expect Mark Zuckerberg’s beliefs about AGI safety would be more important to understand than the general dynamics of moral mazes. (Facebook example deliberately chosen to avoid taking stances on the more likely AGI players, but I think it’s relatively clear which ones are moral mazes).

Most advice is contraindicated for some people, so if it’s not a valid Law, it should only be called to attention, not all else equal given weight or influence beyond what calling something to attention normally merits. Even for Laws, there is no currently legible Law saying that people must or should follow them, that depends on the inscrutable values of Civilization. It’s not a given that people should optimize themselves for being agents. So advice for being an effective agent might be different from advice for being healthy or valuable, or understanding topos theory, or building 5 meters high houses of cards.

For perfectionism, I think never being satisfied with where you’re at now doesn’t mean you can’t take pride in how far you’ve come?

“Don’t feel complacent” feels different from “striving for perfection” to me. The former feels more like making sure your standards don’t drop too much (maintaining a good lower bound), whereas the latter feels more like pushing the upper limit. When I think about complacency, I think about being careful and making sure that I am not e.g. taking the easy way out because of laziness. When I think about perfectionism (in the 12 virtues sense), I think about imagining ways things can be better and finding ways to get closer to that ideal.

I don’t really understand the ‘argument’ virtue so no comment for that.

Master post for ideas about infra-Bayesian physicalism.

Other relevant posts:

• Incorrigibility in IBP

• PreDCA alignment protocol

Infra-Bayesian physicalism is an interesting example in favor of the thesis that the more qualitatively capable an agent is, the less corrigible it is. (a.k.a. “corrigibility is anti-natural to consequentialist reasoning”). Specifically, alignment protocols that don’t rely on value learning become vastly less safe when combined with IBP:

• Example 1: Using steep time discount to disincentivize dangerous long-term plans. For IBP, “steep time discount” just means, predominantly caring about your source code running with particular short inputs. Such a goal strongly incentives the usual convergent instrumental goals: first take over the world, then run your source code with whatever inputs you want. IBP agents just don’t have time discount in the usual sense: a program running late in physical time is just as good as one running early in physical time.

• Example 2: Debate. This protocol relies on a zero-sum game between two AIs. But, the monotonicity principle rules out the possibility of zero-sum! (If $L$ and $-L$ are both monotonic loss functions then $L$ is a constant). So, in a “debate” between IBP agents, they cooperate to take over the world and then run the source code of each debater with the input “I won the debate”.

• Example 3: Forecasting/​imitation (an IDA in particular). For an IBP agent, the incentivized strategy is: take over the world, then run yourself with inputs showing you making perfect forecasts.

The conclusion seems to be, it is counterproductive to use IBP to solve the acausal attack problem for most protocols. Instead, you need to do PreDCA or something similar. And, if acausal attack is a serious problem, then approaches that don’t do value learning might be doomed.

Infradistributions admit an information-theoretic quantity that doesn’t exist in classical theory. Namely, it’s a quantity that measures how many bits of Knightian uncertainty an infradistribution has. We define it as follows:

Let $X$ be a finite set and $\Theta$ a crisp infradistribution (credal set) on $X$, i.e. a closed convex subset of $\Delta X$. Then, imagine someone trying to communicate a message by choosing a distribution out of $\Theta$. Formally, let $Y$ be any other finite set (space of messages), $\theta \in \Delta Y$ (prior over messages) and $K:Y\to \Theta$ (communication protocol). Consider the distribution $\eta :=\theta ⋉K\in \Delta (Y\times X)$. Then, the information capacity of the protocol is the mutual information between the projection on $Y$ and the projection on $X$ according to $\eta$, i.e. $I_{\eta }({pr}_X;{pr}_Y)$. The “Knightian entropy” of $\Theta$ is now defined to be the maximum of $I_{\eta }({pr}_X;{pr}_Y)$ over all choices of $Y$, $\theta$, $K$. For example, if $\Theta$ is Bayesian then it’s $0$, whereas if $\Theta ={\top }_X$, it is $\ln |X|$.

Here is one application^[1] of this concept, orthogonal to infra-Bayesianism itself. Suppose we model inner alignment by assuming that some portion $ϵ$ of the prior $\zeta$ consists of malign hypotheses. And we want to design e.g. a prediction algorithm that will converge to good predictions without allowing the malign hypotheses to attack, using methods like confidence thresholds. Then we can analyze the following metric for how unsafe the algorithm is.

Let $O$ be the set of observations and $A$ the set of actions (which might be “just” predictions) of our AI, and for any environment $\tau$ and prior $\xi$, let $D_{\tau }^{\xi }\left(n\right)\in \Delta (A\times O{)}^n$ be the distribution over histories resulting from our algorithm starting with prior $\xi$ and interacting with environment $\tau$ for $n$ time steps. We have $\zeta =ϵ\mu +(1-ϵ)\beta$, where $\mu$ is the malign part of the prior and $\beta$ the benign part. For any ${\mu }^{\prime }$, consider $D_{\tau }^{ϵ{\mu }^{\prime }+(1-ϵ)\beta }\left(n\right)$. The closure of the convex hull of these distributions for all choices of ${\mu }^{\prime }$ (“attacker policy”) is some ${\Theta }_{\tau }^{\beta }\left(n\right)\in \Delta (A\times O{)}^n$. The maximal Knightian entropy of ${\Theta }_{\tau }^{\beta }\left(n\right)$ over all admissible $\tau$ and $\beta$ is called the malign capacity of the algorithm. Essentially, this is a bound on how much information the malign hypotheses can transmit into the world via the AI during a period of $n$. The goal then becomes finding algorithms with simultaneously good regret bounds and good (in particular, at most polylogarithmic in $n$) malign capacity bounds.

Two deterministic toy models for regret bounds of infra-Bayesian bandits. The lesson seems to be that equalities are much easier to learn than inequalities.

Model 1: Let $A$ be the space of arms, $O$ the space of outcomes, $r:A\times O\to R$ the reward function, $X$ and $Y$ vector spaces, $H\subseteq X$ the hypothesis space and $F:A\times O\times H\to Y$ a function s.t. for any fixed $a\in A$ and $o\in O$, $F(a,o):H\to Y$ extends to some linear operator $T_{a,o}:X\to Y$. The semantics of hypothesis $h\in H$ is defined by the equation $F(a,o,h)=0$ (i.e. an outcome $o$ of action $a$ is consistent with hypothesis $h$ iff this equation holds).

For any $h\in H$ denote by $V\left(h\right)$ the reward promised by $h$:

$$V\left(h\right):=\underset{a\in A}{max}\underset{o\in O:F(a,o,h)=0}{min}r(a,o)$$

Then, there is an algorithm with mistake bound $\dim X$, as follows. On round $n\in N$, let $G_n\subseteq H$ be the set of unfalsified hypotheses. Choose $h_n\in S$ optimistically, i.e.

$$h_n:=\arg \underset{h\in G_n}{max}V\left(h\right)$$

Choose the arm $a_n$ recommended by hypothesis $h_n$. Let $o_n\in O$ be the outcome we observed, $r_n:=r(a_n,o_n)$ the reward we received and $h^{\ast }\in H$ the (unknown) true hypothesis.

If $r_n\ge V\left(h_n\right)$ then also $r_n\ge V\left(h^{\ast }\right)$ (since $h^{\ast }\in G_n$ and hence $V\left(h^{\ast }\right)\le V\left(h_n\right)$) and therefore $a_n$ wasn’t a mistake.

If $r_n<V\left(h_n\right)$ then $F(a_n,o_n,h_n)\ne 0$ (if we had $F(a_n,o_n,h_n)=0$ then the minimization in the definition of $V\left(h_n\right)$ would include $r(a_n,o_n)$). Hence, $h_n\notin G_{n+1}=G_n\cap \ker T_{a_n,o_n}$. This implies $\dim span\left(G_{n+1}\right)<\dim span\left(G_n\right)$. Obviously this can happen at most $\dim X$ times.

Model 2: Let the spaces of arms and hypotheses be

$$A:=H:=S^d:=\{x\in R^{d+1}\mid \parallel x\parallel =1\}$$

Let the reward $r\in R$ be the only observable outcome, and the semantics of hypothesis $h\in S^d$ be $r\ge h\cdot a$. Then, the sample complexity cannot be bound by a polynomial of degree that doesn’t depend on $d$. This is because Murphy can choose the strategy of producing reward $1-ϵ$ whenever $h\cdot a\le 1-ϵ$. In this case, whatever arm you sample, in each round you can only exclude ball of radius $\approx \sqrt{2ϵ}$ around the sampled arm. The number of such balls that fit into the unit sphere is $\Omega \left({ϵ}^{-\frac{1}{2}d}\right)$. So, normalized regret below $ϵ$ cannot be guaranteed in less than that many rounds.

One of the postulates of infra-Bayesianism is the maximin decision rule. Given a crisp infradistribution $\Theta$, it defines the optimal action to be:

$$a^{\ast }\left(\Theta \right):=\arg \underset{a}{max}\underset{\mu \in \Theta }{min}{E}_{\mu }\left[U\right(a\left)\right]$$

Here $U$ is the utility function.

What if we use a different decision rule? Let $t\in [0,1]$ and consider the decision rule

$$a_t^{\ast }\left(\Theta \right):=\arg \underset{a}{max}\left(t\underset{\mu \in \Theta }{min}{E}_{\mu }\right[U\left(a\right)]+(1-t\left)\underset{\mu \in \Theta }{max}{E}_{\mu }\right[U\left(a\right)\left]\right)$$

For $t=1$ we get the usual maximin (“pessimism”), for $t=0$ we get maximax (“optimism”) and for other values of $t$ we get something in the middle (we can call “$t$-mism”).

It turns out that, in some sense, this new decision rule is actually reducible to ordinary maximin! Indeed, set

$${\mu }_t^{\ast }:=\arg \underset{\mu }{max}{E}_{\mu }\left[U\right(a_t^{\ast }\left)\right]$$

$${\Theta }_t:=t\Theta +(1-t){\mu }_t^{\ast }$$

Then we get

$$a^{\ast }\left({\Theta }_t\right)=a_t^{\ast }\left(\Theta \right)$$

More precisely, any pessimistically optimal action for ${\Theta }_t$ is $t$-mistically optimal for $\Theta$ (the converse need not be true in general, thanks to the arbitrary choice involved in ${\mu }_t^{\ast }$).

To first approximation it means we don’t need to consider $t$-mistic agents since they are just special cases of “pessimistic” agents. To second approximation, we need to look at what the transformation of $\Theta$ to ${\Theta }_t$ does to the prior. If we start with a simplicity prior then the result is still a simplicity prior. If $U$ has low description complexity and $t$ is not too small then essentially we get full equivalence between “pessimism” and $t$-mism. If $t$ is small then we get a strictly “narrower” prior (for $t=0$ we are back at ordinary Bayesianism). However, if $U$ has high description complexity then we get a rather biased simplicity prior. Maybe the latter sort of prior is worth considering.

Infra-Bayesianism can be naturally understood as semantics for a certain non-classical logic. This promises an elegant synthesis between deductive/​symbolic reasoning and inductive/​intuitive reasoning, with several possible applications. Specifically, here we will explain how this can work for higher-order logic. There might be holes and/​or redundancies in the precise definitions given here, but I’m quite confident the overall idea is sound.

We will work with homogenous ultracontributions (HUCs). $\square X$ will denote the space of HUCs over $X$. Given $\mu \in \square X$, $S\left(\mu \right)\subseteq {\Delta }^{c}X$ will denote the corresponding convex set. Given $p\in \Delta X$ and $\mu \in \square X$, $p:\mu$ will mean $p\in S\left(\mu \right)$. Given $\mu ,\nu \in \square X$, $\mu ⪯\nu$ will mean $S\left(\mu \right)\subseteq S\left(\nu \right)$.

Syntax

Let $T^{\iota }$ denote a set which we interpret as the types of individuals (we allow more than one). We then recursively define the full set of types $T$ by:

• $0\in T$ (intended meaning: the uninhabited type)

• $1\in T$ (intended meaning: the one element type)

• If $\alpha \in T^{\iota }$ then $\alpha \in T$

• If $\alpha ,\beta \in T$ then $\alpha +\beta \in T$ (intended meaning: disjoint union)

• If $\alpha ,\beta \in T$ then $\alpha \times \beta \in T$ (intended meaning: Cartesian product)

• If $\alpha \in T$ then $\left(\alpha \right)\in T$ (intended meaning: predicates with argument of type $\alpha$)

For each $\alpha ,\beta \in T$, there is a set $F_{\alpha \to \beta }^0$ which we interpret as atomic terms of type $\alpha \to \beta$. We will denote $V_{\alpha }^0:=F_{1\to \alpha }^0$. Among those we distinguish the logical atomic terms:

• ${pr}_{\alpha \beta }\in F_{\alpha \times \beta \to \alpha }^0$

• $i_{\alpha \beta }\in F_{\alpha \to \alpha +\beta }^0$

• Symbols we will not list explicitly, that correspond to the algebraic properties of $+$ and $\times$ (commutativity, associativity, distributivity and the neutrality of $0$ and $1$). For example, given $\alpha ,\beta \in T$ there is a “commutator” of type $\alpha \times \beta \to \beta \times \alpha$.

• ${=}_{\alpha }\in V_{(\alpha \times \alpha )}^0$

• ${diag}_{\alpha }\in F_{\alpha \to \alpha \times \alpha }^0$

• $({)}_{\alpha }\in V_{\left(\right(\alpha )\times \alpha )}^0$ (intended meaning: predicate evaluation)

• $\perp \in V_{\left(1\right)}^0$

• $\top \in V_{\left(1\right)}^0$

• ${\vee }_{\alpha }\in F_{\left(\alpha \right)\times \left(\alpha \right)\to \left(\alpha \right)}^0$

• ${\wedge }_{\alpha }\in F_{\left(\alpha \right)\times \left(\alpha \right)\to \left(\alpha \right)}^0$ [EDIT: Actually this doesn’t work because, except for finite sets, the resulting mapping (see semantics section) is discontinuous. There are probably ways to fix this.]

• ${\exists }_{\alpha \beta }\in F_{(\alpha \times \beta )\to \left(\beta \right)}^0$

• ${\forall }_{\alpha \beta }\in F_{(\alpha \times \beta )\to \left(\beta \right)}^0$ [EDIT: Actually this doesn’t work because, except for finite sets, the resulting mapping (see semantics section) is discontinuous. There are probably ways to fix this.]

• Assume that for each $n\in N$ there is some $D_n\subseteq \square \left[n\right]$: the set of “describable” ultracontributions [EDIT: it is probably sufficient to only have the fair coin distribution in $D_2$ in order for it to be possible to approximate all ultracontributions on finite sets]. If $\mu \in D_n$ then $┌\mu ┐\in V_{\left({\sum }_{i=1}^{n}1\right)}$

We recursively define the set of all terms $F_{\alpha \to \beta }$. We denote $V_{\alpha }:=F_{1\to \alpha }$.

• If $f\in F_{\alpha \to \beta }^0$ then $f\in F_{\alpha \to \beta }$

• If $f_1\in F_{{\alpha }_1\to {\beta }_1}$ and $f_2\in F_{{\alpha }_2\to {\beta }_2}$ then $f_1\times f_2\in F_{{\alpha }_1\times {\alpha }_2\to {\beta }_1\times {\beta }_2}$

• If $f_1\in F_{{\alpha }_1\to {\beta }_1}$ and $f_2\in F_{{\alpha }_2\to {\beta }_2}$ then $f_1+f_2\in F_{{\alpha }_1+{\alpha }_2\to {\beta }_1+{\beta }_2}$

• If $f\in F_{\alpha \to \beta }$ then $f^{-1}:F_{\left(\beta \right)\to \left(\alpha \right)}$

• If $f\in F_{\alpha \to \beta }$ and $g\in F_{\beta \to \gamma }$ then $g\circ f\in F_{\alpha \to \gamma }$

Elements of $V_{\left(\alpha \right)}$ are called formulae. Elements of $V_{\left(1\right)}$ are called sentences. A subset of $V_{\left(1\right)}$ is called a theory.

Semantics

Given $T\subseteq V_{\left(1\right)}$, a model $M$ of $T$ is the following data. To each $\alpha \in T$, there must correspond some compact Polish space $M\left(t\right)$ s.t.:

• $M\left(0\right)=\varnothing$

• $M\left(1\right)=pt$ (the one point space)

• $M(\alpha +\beta )=M\left(\alpha \right)\bigsqcup M\left(\beta \right)$

• $M(\alpha \times \beta )=M\left(\alpha \right)\times M\left(\beta \right)$

• $M\left(\right(\alpha \left)\right)=\square M\left(\alpha \right)$

To each $f\in F_{\alpha \to \beta }$, there must correspond a continuous mapping $M\left(f\right):M\left(\alpha \right)\to M\left(\beta \right)$, under the following constraints:

• $pr$, $i$, $diag$ and the “algebrators” have to correspond to the obvious mappings.

• $M\left({=}_{\alpha }\right)={\top }_{{diag}_{M\left(\alpha \right)}}$. Here, ${diag}_X\subseteq X\times X$ is the diagonal and ${\top }_C\in \square X$ is the sharp ultradistribution corresponding to the closed set $C\subseteq X$.

• Consider $\alpha \in T$ and denote $X:=M\left(\alpha \right)$. Then, $M\left(\right({)}_{\alpha })={\top }_{\square X}⋉{id}_{\square X}$. Here, we use the observation that the identity mapping ${id}_{\square X}$ can be regarded as an infrakernel from $\square X$ to $X$.

• $M\left(\perp \right)={\perp }_{pt}$

• $M\left(\top \right)={\top }_{pt}$

• $S\left(M\right(\vee \left)\right(\mu ,\nu \left)\right)$ is the convex hull of $S\left(\mu \right)\cup S\left(\nu \right)$

• $S\left(M\right(\wedge \left)\right(\mu ,\nu \left)\right)$ is the intersection of $S\left(\mu \right)\cup S\left(\nu \right)$

• Consider $\alpha ,\beta \in T$ and denote $X:=M\left(\alpha \right)$, $Y:=M\left(\beta \right)$ and $pr:X\times Y\to Y$ the projection mapping. Then, $M\left({\exists }_{\alpha \beta }\right)\left(\mu \right)={pr}_{\ast }\mu$.

• Consider $\alpha ,\beta \in T$ and denote $X:=M\left(\alpha \right)$, $Y:=M\left(\beta \right)$ and $pr:X\times Y\to Y$ the projection mapping. Then, $p:M\left({\forall }_{\alpha \beta }\right)\left(\mu \right)$ iff for all $q\in {\Delta }^c(X\times Y)$, if ${pr}_{\ast }q=p$ then $q:\mu$.

• $M(f_1\times f_2)=M\left(f_1\right)\times M\left(f_2\right)$

• $M(f_1+f_2)=M\left(f_1\right)\bigsqcup M\left(f_2\right)$

• $M\left(f^{-1}\right)\left(\mu \right)=M\left(f{)}^{\ast }\right(\mu )$.

• $M(g\circ f)=M\left(g\right)\circ M\left(f\right)$

• $M(┌\mu ┐)=\mu$

Finally, for each $\varphi \in T$, we require $M\left(\varphi \right)={\top }_{pt}$.

Semantic Consequence

Given $\varphi \in V_{\left(1\right)}$, we say $M\models \varphi$ when $M\left(\varphi \right)={\top }_{pt}$. We say $T\models \varphi$ when for any model $M$ of $T$, $M\models \varphi$. It is now interesting to ask what is the computational complexity of deciding $T\models \varphi$. [EDIT: My current best guess is co-RE]

Applications

As usual, let $A$ be a finite set of actions and $O$ be a finite set of observation. Require that for each $o\in O$ there is ${\sigma }_o\in T^{\iota }$ which we interpret as the type of states producing observation $o$. Denote ${\sigma }_{\ast }:={\sum }_{o\in O}{\sigma }_o$ (the type of all states). Moreover, require that our language has the nonlogical symbols $s_0\in V_{\left({\sigma }_{\ast }\right)}^0$ (the initial state) and, for each $a\in A$, $K_a\in F_{{\sigma }_{\ast }\to \left({\sigma }_{\ast }\right)}^0$ (the transition kernel). Then, every model defines a (pseudocausal) infra-POMDP. This way we can use symbolic expressions to define infra-Bayesian RL hypotheses. It is then tempting to study the control theoretic and learning theoretic properties of those hypotheses. Moreover, it is natural to introduce a prior which weights those hypotheses by length, analogical to the Solomonoff prior. This leads to some sort of bounded infra-Bayesian algorithmic information theory and bounded infra-Bayesian analogue of AIXI.

In the anthropic trilemma, Yudkowsky writes about the thorny problem of understanding subjective probability in a setting where copying and modifying minds is possible. Here, I will argue that infra-Bayesianism (IB) leads to the solution.

Consider a population of robots, each of which in a regular RL agent. The environment produces the observations of the robots, but can also make copies or delete portions of their memories. If we consider a random robot sampled from the population, the history they observed will be biased compared to the “physical” baseline. Indeed, suppose that a particular observation $c$ has the property that every time a robot makes it, 10 copies of them are created in the next moment. Then, a random robot will have $c$ much more often in their history than the physical frequency with which $c$ is encountered, due to the resulting “selection bias”. We call this setting “anthropic RL” (ARL).

The original motivation for IB was non-realizability. But, in ARL, Bayesianism runs into issues even when the environment is realizable from the “physical” perspective. For example, we can consider an “anthropic MDP” (AMDP). An AMDP has finite sets of actions ($A$) and states ($S$), and a transition kernel $T:A\times S\to \Delta \left(S^{\ast }\right)$. The output is a string of states instead of a single state, because many copies of the agent might be instantiated on the next round, each with their own state. In general, there will be no single Bayesian hypothesis that captures the distribution over histories that the average robot sees at any given moment of time (at any given moment of time we sample a robot out of the population and look at their history). This is because the distributions at different moments of time are mutually inconsistent.

[EDIT: Actually, given that we don’t care about the order of robots, the signature of the transition kernel should be $T:A\times S\to \Delta N^S$]

The consistency that is violated is exactly the causality property of environments. Luckily, we know how to deal with acausality: using the IB causal-acausal correspondence! The result can be described as follows: Murphy chooses a time moment $n\in N$ and guesses the robot policy $\pi$ until time $n$. Then, a simulation of the dynamics of $(\pi ,T)$ is performed until time $n$, and a single history is sampled from the resulting population. Finally, the observations of the chosen history unfold in reality. If the agent chooses an action different from what is prescribed, Nirvana results. Nirvana also happens after time $n$ (we assume Nirvana reward $1$ rather than $\infty$).

This IB hypothesis is consistent with what the average robot sees at any given moment of time. Therefore, the average robot will learn this hypothesis (assuming learnability). This means that for $n\gg \frac{1}{1-\gamma }\gg 0$, the population of robots at time $n$ has expected average utility with a lower bound close to the optimum for this hypothesis. I think that for an AMDP this should equal the optimum expected average utility you can possibly get, but it would be interesting to verify.

Curiously, the same conclusions should hold if we do a weighted average over the population, with any fixed method of weighting. Therefore, the posterior of the average robot behaves adaptively depending on which sense of “average” you use. So, your epistemology doesn’t have to fix a particular method of counting minds. Instead different counting methods are just different “frames of reference” through which to look, and you can be simultaneously rational in all of them.