LessWrongModify

2025-12-03 22:59:34

Published on December 3, 2025 2:59 PM GMT

Eliezer Yudkowsky has, on several occasions, claimed that AI’s success at protein folding was essentially predictable. His reasoning (e.g., here) is straightforward and convincing: proteins in our universe fold reliably; evolution has repeatedly found foldable and functional sequences; therefore the underlying energy landscapes must possess a kind of benign structure. If evolution can navigate these landscapes, then, with enough data and compute, machine learning should recover the mapping from amino-acid sequence to three-dimensional structure.

This account has rhetorical and inductive appeal. It treats evolution as evidence about the computational nature of protein folding and interprets AlphaFold as a natural consequence of biological priors. But the argument, as usually presented, fails to acknowledge what would be required for it to count as a formal heuristic. It presumes that evolutionary success necessitates the existence of a simple, learnable mapping. It presumes that the folding landscape is sufficiently smooth that the space of biologically relevant proteins is intrinsically easy. And it presumes that the success of a massive deep-learning model confirms that the problem was always secretly tractable.

These presumptions rely on an unspoken quantifier: for all proteins relevant to life, folding is easy. But this “for all” is not legitimate in a complexity-theoretic context unless the instance class has a precise and bounded description. Yudkowsky instead appeals to whatever evolution happened to discover. Evolution’s search process, however, is not a polytime algorithm but an unbounded historical trajectory with astronomical parallelism, billions of years of runtime, and immense filtering by selection pressures. Without explicit bounds, “evolution succeeded” does not imply anything about the inherent computational character of the underlying mapping. It merely establishes that a particular contingent subset of sequences—those the biosphere retained—happened to be foldable by natural dynamics.

If we shift to formal models, the general protein-folding problem remains NP-hard under standard abstraction schemes. That does not mean biological folding is NP-hard, only that no claim about the general tractability of the sequence to structure mapping can be inferred from evolutionary success. What matters for tractability is not the full space of possible proteins but the restricted subset that life explores. Yudkowsky’s argument, by treating evolutionary selection as direct evidence of easy energy landscapes, smuggles in the structural properties of that restricted set without acknowledging that these properties are exactly what must be demonstrated—not simply asserted.

The right computational picture looks very different. The biosphere does not sample uniformly from all possible sequences. Instead, it occupies a tiny, closed, highly structured subset of sequence space—an extraordinarily low-Kolmogorov-complexity region characterized by a few thousand fold families, extensive modularity, and strong physical constraints on designability. This subset bears almost no resemblance to the adversarial or worst-case instances that drive NP-hardness proofs.

$\begin{array}{ccc}{B}_n& \ll & {\Sigma }^n\\ \mathrm{KC}\left(B_n\right)& \ll & \mathrm{KC}\left({\Sigma }^n\right)\\ \mathrm{Struct}\left(B_n\right)& ⋐& {\mathrm{Struct}}_{adv}\\ F{|}_{B_n}& \in & P/poly\text{but}F\notin P/poly\end{array}$

Once attention is confined to that biologically realized region, the folding map ceases to be the general NP-hard problem and becomes a promise problem over a heavily compressed instance class. The problem is not hard, it's just big.

Seen this way, the achievement of AlphaFold is not evidence that “protein folding was always solvable,” but evidence that modern machine learning can use enormous non-uniform information—training data, evolutionary alignments, known structures—to approximate a mapping defined over a small and highly regularized domain. The training process acts as a vast preprocessing step, analogous to non-uniform advice in complexity theory. The final trained model is essentially a polytime function augmented by a massive advice string (its learned parameters), specialized to a single distribution. Evolution itself plays a similar role: after billions of years of search, it has curated only those sequences that belong to a region of the landscape where folding is stable, kinetically accessible, and robust to perturbation. The process is not evidence that folding is uniformly simple; it is evidence that evolution found a tractable island inside an intractable ocean.

This distinction matters because it reframes the “predictability” of AlphaFold’s success. Yudkowsky presents folding as solvable because biological energy landscapes are smooth enough to make evolution effective. But smoothness on the evolutionary subset does not entail smoothness on the entire space; nor does it imply that this subset is algorithmically accessible without vast volumes of preprocessing. A complexity-theoretic interpretation views the success of deep learning not as the discovery of a simple universal rule but as the extraction of structure from a domain that has already been heavily pruned, compressed, and optimized by natural history. The learning system inherits its tractability from the fact that the problem has been pre-worked into a low-entropy form.

There is therefore a straightforward computational reason why the “evolution shows folding is easy” argument does not succeed as an explanation: it conflates a historical process without resource bounds with an algorithmic claim that requires them. It interprets the existence of foldable proteins as proof of benign complexity rather than as the output of a long, unbounded filtration that carved out a tractable subclass. The right explanatory frame is not “energy landscapes are nice,” but “biology inhabits a closed problem class with small descriptive complexity, and our algorithms exploit vast non-uniform information about that class.”

Yudkowsky’s argument gestures toward the right conclusion—that solvability was unsurprising—but gives the wrong reason. The crucial structure lies not in universal physics but in the finite, closed domain evolution left to us, and in the immense preprocessing our models perform before they ever encounter a new sequence. The success of AlphaFold was predictable only conditional on the recognition that the real problem is not worst-case folding but folding within a compact distribution carved out by evolutionary history and indexed in publicly available data. What makes the achievement unsurprising is not that physical energy landscapes are globally smooth, but that the domain evolution generated is sufficiently structured, and sufficiently well-sampled, to permit high-fidelity interpolation.

In essence, no one has solved the actual problem, because any solver specialized to the evolutionary subset is guaranteed to fail once the promise is removed; outside that tightly curated domain, the mapping reverts to an unbounded and intractable instance class.

(Context: much contemporary discourse treats machine learning as if it were solving an analytic problem over a vast, effectively unbounded function space—an optimization in a continuous domain, governed by gradient dynamics and statistical generalization. But what learning systems actually deliver, when examined through a computational or logical lens, is a highly non-uniform procedure specialized to a sharply delimited region of instance space. Mixing the analytic metaphor “learning a function over a vast continuous space” with conclusions that require logical quantification “the problem is easy for all relevant inputs” invites people to mistake interpolation on a compact manifold for global tractability. But computation is always local: effective behavior emerges once the space is sufficiently structured, compressed, or bounded by a promise. The solution: Constructive Logic, statements should be made relative to well-defined objects, not idealized totalities.)

2025-12-03 22:49:08

Published on December 3, 2025 2:49 PM GMT

It’s early. 0100. I’ve just come home from walking a guest at my latest party to her bus stop. Cleaned up a bit. Now I’m sitting here. A few interesting topics came up

For a while I talked to a the smartest man in St Vincent, the philosophy PHD, hedge fund dude and Mats guy about dualism vs physicalism. Hedge fund guy said he used to be a dualist but changed his mind when he heard a good counterargument. The argument was roughly that physical things seem distinct, but actually the way we draw boundaries around them is arbitrary. He perceived himself as distinct from the sofa he was sitting on and the sofa as distinct from the small pillows on it. An alien visiting earth might see them all as one object. It’s unclear why any one set of boundaries would be more correct. Even on the level of a boundary, all objects bleed into each other at an atomic level anyway. So, in short there is no objective, crisp distinction between physical objects. He believes that minds are distinct. It seems obvious to him that his mind is separate from mine. But if minds are based on physical things then they must also flow into each other which can’t be the case. Hence minds cannot be physical.

There were a few objections to this. First, maybe minds do flow into each other in a similar way. The thoughts and ideas of others shape my thoughts and ideas. Even non verbal things, like a friend anxiously pacing next to me, change my mood and state. Just like an alien may draw different boundaries around objects, so they could draw different boundaries around where a “mind” begins and ends. This is reminicent of the spiderweb argument from years ago. The story goes that some spiders have tiny brains but display much smarter behaviour than they should. It turns out that the offload memory and some computation to their web. Is their web part of their mind/brain? The second objection was similar but slightly different. So maybe boundaries and the talk of what objects are real or not is just misleading. There is base reality. The lines we draw around things are just useful abstractions. The most basic physical laws and particles (or the stream of qualia you experience if you want to be precise) is Real with a capital R. A jumbo jet is real in the sense that the label I apply to certain configurations of atoms may or may not accurately describe a given place in space and time. But it’s not Real in an objective sense and an alien or different person could well categorize the same atoms differently. (e.g: seeing a metal shell and an interior hollow space as two different components).

At some point the conversation moved on. The smartest man was a Christian and described himself as a dualist but he actually held a computational view of consciousness. I asked him his intuitions about replacing his brain atom by atom with computational equivalent silicone processors. He thought he’d be the same person. We wasted a bit of time discussing the definition of dualism vs physicalism and whether computationalism was a form of dualism or not really? He argued it was because you believe the mind is a separate kind of thing. A pattern rather than a specific physical arrangement of atoms. Me and Andrea argued that the computationalism still grounded out in concrete reality. The mind was a pattern but that pattern was instantiated in and entirely dependent on the physical world. Yes it could exist on different kinds of substrate or physical material but still it was a physical phenomenon just like other kinds of pattern. e.g: rain. Dualism holds that minds are a separate, non-physical thing entirely. That the destruction of physical objects could sever the connection to the mind, but that the mind still exists independently. So by our definition he wasn’t really a dualist.

After this I left, let people in and generally hovered around. When I came back the conversation had turned to identity and the teleport experiment. Andrea had left and a bit of the way in the polish power couple had joined. The conversation boiled down to personspace vs continuity of consciousness views of identity. There wasn’t a good resolution. They played around with different examples for a bit but the core difference in intuitions always remained. I think over the years I’ve come to the view that philosophy of identity is similar to ethics. It is possible to make meaningful progress, to have thought experiments which make you reify your beliefs etc… But still it ultimately rests not on a shared external reality but on a set of intuitions that people hold. Just like in ethics, even if you do it well sometimes you’ll reach moral bedrock and just discover that two people hold different axiomatic beliefs or tradeoff rations between moral goods, so in identity some people just have very different views of what it mean to be a person. Hmmmm. Maybe. Or maybe with enough prodding with various “simulated minds but running out of order/inparallel/etc…” arguments and the goldfish gun most continuity of consciousness people should on reflection change their view. I’m unsure.

Other things happened. People talked. At some point while walking outside to get ramen I spoke to the scientist whose parents were atheistic christians. He’d been to China recently where he met one of my close friends. He observed how safe China was and felt. He recounted how at a hike starting spot in a large city there was an open container with water bottles and a box for money to pay if you take one. I’ve heard similar stories from my friend about charging banks or various other things. I heard that public safety was far lower in the past and China was lower social trust. I wonder what’s driven the change? A few theories

There’s a large technological overhang for crime/bad behaviour reduction. CCTV and facial recognition and effective policing. The west ignores the tech. China embraces it, with CCTV everywhere and swift punishment. This creates an environment which is naturally high trust. Doing anything bad is very likely to be punished/caught. Also, because no one does bad stuff generally it becomes even more culturally frowned upon and even easier to catch because the ratio of police:criminal goes up as the number of criminals goes down but police funding stays roughly constant. econ grown = more prosperity/wealth = higher trust more commercial culture, the slow escape from low trust communist/authoritarian culture they’re east asian. Most developed east asian countries have high social trust and safety (Japan, Taiwan, Korea, etc…). Could be genetic. Could be culture I came home and eventually sat down and talked to a Ukrainian girl. She had an experience with being cancelled a while ago for writing a fairly banal post comparing moral outrage at sexual abuse of children to broad moral acceptance or at least lack of real concern with all the other ways in which parents can and do severely limit their children’s autonomy or disrespect their consent. We talked a bit. She essentially was concerned about the same problems I was when I was a teenager. Moloch, the inevitable grind of evolution, and what back then I had termed the impossibility of “breaking the chains of causality”. Her point was roughly that we are human beings, but many of our desires, thoughts and actions are shaped by our genes. These are things we do not choose, but rather things that we are enslaved to. We should strive to rise above that, to consciously fight those desires and try to cut them out of ourselves. I broadly agree with her but my counterargument was the standard one. Every desire, impulse, etc… which makes up your utility function is a product of processes outside of your control. Nature. Nurture. Random chance if the universe is not deterministic. Why assume that all desires stemming from genes/nature are bad and those stemming from nurture etc… are fine? Aren’t they all equally arbitrary? Isn’t a better criteria to determine on reflection which of your present desires you want and do not want and then to work on excising or resisting those you do not want to control you. e.g: I like/respect attractive people more. On reflection I would rather not do this and so I fight against this tendency in myself. I don’t want people around me to be tortured and to horribly suffer for no reason. I know this desire also comes from evolution (having your tribe/family suffer is bad if you’re related, maybe reciprocity norms are adaptive at the group and individual level etc…), but it’s a desire I want to have.

Ultimately my conclusion here is similar to the one I made as a child. If you cut away every part of you that was instilled in you by moloch or processes outside of your control, you are left with nothing. Every part of you is bound by the chains of causality. Every decision comes down the the remorseless logic of the physical universe. To somehow break that causality is to also break the machine and set of rules which enable the system you draw a boundary around and call “me” to exist and function. We live in a prison but we also the chains.

Still, maybe that’s too dramatic. Breaking free of causality is impossible. More reflection and consciously rejecting your base desires, cultivating virtue and trying to lift your head out of the mud and towards the stars is something worth doing.

On a meta-level, there’s something terrifying and self-referential about this conversation. Rationally I know my thoughts arise from a deterministic or at best probabilistic process. Intuitively I always thought my thoughts were unique and somehow pure and above the physical world. The fact that my ideas and aim were so different from those around me growing up reinforced that. I felt like I stood above and apart from the masses. Now I meet another smart, autistic eastern European and they happen to have pretty much the exact same obsession with rising above the animal inside and breaking the stranglehold evolution has on mind and body. I don’t think that’s a coincidence. Strange how a conversation about breaking free of evolution/environment makes me realize how beholden to both I am.

2025-12-03 22:35:28

Published on December 3, 2025 2:35 PM GMT

Introduction

In this post, we introduce contributions and supracontributions^[1], which are basic objects from infra-Bayesianism that go beyond the crisp case (the case of credal sets). We then define supra-POMDPs, a generalization of partially observable Markov decision processes (POMDPs). This generalization has state transition dynamics that are described by supracontributions.

We use supra-POMDPs to formalize various Newcombian problems in the context of learning theory where an agent repeatedly encounters the problem. The one-shot version of these problems are well-known to highlight flaws with classical decision theories.^[2] In particular, we discuss the opaque, transparent, and epsilon-noisy versions of Newcomb's problem, XOR blackmail, and counterfactual mugging.

We conclude by stating a theorem that describes when optimality for the supra-POMDP relates to optimality for the Newcombian problem. This theorem is significant because it gives a sufficient condition under which infra-Bayesian decision theory (IBDT) can approximate the optimal decision. Furthermore, we demonstrate through the examples that IBDT is optimal for problems for which evidential and causal decision theory fail. 

Fuzzy infra-Bayesianism

Contributions, a generalization of probability distributions, are defined as follows.

Definition: Contribution

A contribution on a finite set $X$ is a function^[3] $\theta :X\to [0,1]$ such that ${\sum }_{x\in X}\theta \left(x\right)\le 1.$ The set of contributions on $X$ is denoted by ${\Delta }^{C}X$.

Given $A\subseteq X,$ we write $\theta \left(A\right)$ to denote ${\sum }_{x\in A}\theta \left(x\right).$ A partial order on ${\Delta }^{C}X$ is given by ${\theta }_1{\le }_C{\theta }_2$ if for all subsets $A\subseteq X,$ ${\theta }_1\left(A\right)\le {\theta }_2\left(A\right).$ For example, the constant-zero function 0 is a contribution that lies below every element in ${\Delta }^{C}X$ in the partial order. A set of contributions $\Theta$ is downward closed if for all $\theta \in \Theta ,$ ${\theta }^{\prime }{\le }_C\theta$ implies ${\theta }^{\prime }\in \Theta .$ Given $\Theta \subseteq {\Delta }^{C}X,$ the downward closure of $\Theta$ in ${\Delta }^{C}X$ is defined by 

Figure 1 illustrates a set of contributions together with its downward closure. 

The set of contributions shown in Figure 1 together with its downward closure is an example of a supracontribution, defined as follows. 

Definition: Supracontribution

A supracontribution on $X$ is a set of contributions $\Theta \subseteq {\Delta }^{C}X$ such that

1. $0\in \Theta$,
2. $\Theta$ is closed,
3. $\Theta$ is convex, and 
4. $\Theta$ is downward closed.

The set of supracontributions on $X$ is denoted by ${\square }^{C}X$.

Figure 2 shows another example of a supracontribution. 

Supracontributions can be regarded as fuzzy sets of distributions, namely sets of distributions in which membership is described by a value in $[0,1]$ rather than $\{0,1\}.$ In particular, the membership $\Gamma (\theta ,\Theta )$ of $\theta \in \Delta X$ in $\Theta \in {\square }^{C}X$ is given by 

where $p\theta$ denotes the scaling of $\theta$ by $p.$ See Figure 3 for two examples. Note that $\Gamma$ is well-defined since all supracontributions contain 0. By this viewpoint, supracontributions can be seen as a natural generalization of credal sets, which are "crisp" or ordinary sets of distributions. 

There is a natural embedding $\tau :\square X\to {\square }^{C}X$ of credal sets on $X$ into the space of supracontributions on $X.$ Let ${\perp }_X:=\left\{0\right\}.$ Define $\tau \left(\Theta \right):={\Theta }^{\downarrow }\cup {\perp }_X.$ Note that under this definition, $\tau \left(\varnothing \right)={\perp }_X$ (and otherwise the union with ${\perp }_X$ in the definition of $\tau$ is redundant). 

Generalizing the notion of expected value, we write $E_{\theta }\left[L\right]:={\sum }_{x\in X}\theta \left(x\right)L\left(x\right).$ We define expectation (similarly as in the crisp case) as the max over all expectations for elements of the supracontribution. By definition, a supracontribution is closed and thus this notion of expectation is well-defined. 

Definition: Expectation with respect to a supracontribution

Given a continuous function $L:X\to [0,1]$ and $\Theta \in {\square }^{C}X,$ define the expectation of $L$ with respect to $\Theta$ by 

$$E_{\Theta }\left[L\right]:=\underset{\theta \in \Theta }{max}{E}_{\theta }\left[L\right].$$

Let $\tilde{\Theta }\subseteq {\Delta }^{C}X$ denote a non-empty set of contributions. Then ${sup}_{\theta \in \tilde{\Theta }}{E}_{\theta }\left[L\right]={max}_{\theta \in \overline{\text{ch}(\tilde{\Theta }{)}^{\downarrow }}}{E}_{\theta }\left[L\right]$ where $\text{ch}$ denotes convex hull and $\overline{\cdot }$ denotes closure. Therefore, in the context of optimization we may always replace a non-empty set of contributions by the supracontribution obtained by taking the convex, downward, and topological closure.

Recall that environments in the classical theory and in crisp infra-Bayesianism have type $(A\times O{)}^{\ast }\times A\to \Delta O.$ We generalize this notion to the fuzzy setting using semi-environments.^[4]

Definition: Semi-environment

A semi-environment is a map of the form $\mu :(A\times O{)}^{\ast }\times A\to {\Delta }^{C}O.$

The interaction of a semi-environment and a policy $\pi :(A\times O{)}^{\ast }\rightharpoonup A$ determines a contribution on destinies ${\mu }^{\pi }\in {\Delta }^C(A\times O{)}^{\omega }.$^[5]

Definition: (Fuzzy) law

A (fuzzy) law generated by a set of semi-environments $E$ is a map $\Lambda :\Pi \to {\square }^C(A\times O{)}^{\omega }$ such that for all $\pi \in \Pi ,$ $\Lambda \left(\pi \right)={\overline{\text{ch}\left(\right\{{\mu }^{\pi }|\mu \in E\left\}\right)}}^{\downarrow }$ where $\text{ch}$ denotes convex hull and $\overline{\cdot }$ denotes closure. 

Fuzzy Supra-POMDPs

Our tool for formalizing Newcombian problems using the mathematical objects described in the last section is fuzzy supra-POMDPs, a generalization of partially observable Markov decision processes (POMDPs). Given a set of states $S$ and a contribution $\theta \in {\Delta }^C\left(S\right),$ the missing probability mass, $1-\theta \left(S\right),$ can be interpreted as the probability of a logical contradiction.

Under a fuzzy supra-POMDP model, uncertainty of the initial state is described by an initial supracontribution over states. Similarly to the state transition dynamics of a crisp supra-POMDP as defined in the preceding post, the state transition dynamics of a fuzzy supra-POMDP are multivalued. Given a state and action, the transition suprakernel returns a supracontribution, and the true dynamics are described by any element of the supracontribution. 

A significant feature of fuzzy supra-POMDPs is that for some state $s$ and action $a,$ we may have $T(s,a)={\perp }_S,$ which corresponds to a logical contradiction in which the state transition dynamics come to a halt. We use this feature to model Newcombian problems where it is assumed there is a perfect predictor Omega predicting an agent's policy. When an action deviates from the predicted policy (which is encoded in the state), the transition kernel returns ${\perp }_S.$ 

We formally define fuzzy supra-POMDPs as follows. 

Definition: Fuzzy supra-POMDP

A fuzzy supra-partially observable Markov decision process (supra-POMDP) is a tuple $(S,{\Theta }_0,A,O,T,B)$ where

• $S$ is a set of states,
• ${\Theta }_0\in {\square }^{C}S$ is an initial supracontribution over states,
• $A$ is a set of actions,
• $O$ is a set of observations,
• $T:S\times A\to {\square }^{C}S$ is a transition suprakernel,^[6]
• $B:S\to O$ is an observation mapping.

Defining laws from fuzzy supra-POMDPs

Every fuzzy supra-POMDP defines a (fuzzy) law. The construction is similar to the construction of a crisp law given a crisp supra-POMDP, which is discussed in the preceding post. A copolicy to a fuzzy supra-POMDP is a map $\sigma :(S\times A{)}^{\ast }\to {\Delta }^{C}S$ that is consistent with the transition suprakernel. More specifically, given a history of states and actions, the transition kernel determines a supracontribution from the most recent state and action. The copolicy can be thought of as a map that selects a contribution from that supracontribution.

Definition: Copolicy to a fuzzy supra-POMDP

Let $M=(S,{\Theta }_0,A,O,T,B)$ be a fuzzy supra-POMDP. A map $\sigma :(S\times A{)}^{\ast }\to {\Delta }^{C}S$ is an $M$-copolicy if

1.  $\sigma \left(ϵ\right)\in {\Theta }_0$ for the empty string $ϵ,$ and
2. For all non-empty strings $hsa\in (S\times A{)}^{\ast }$, $\sigma \left(hsa\right)\in T(s,a)$. 

An $M$-copolicy $\sigma :(S\times A{)}^{\ast }\to {\Delta }^{C}S$ and the observation map $B:S\to O$ of $M$ together determine a semi-environment ${\mu }_{\sigma }:(A\times O{)}^{\ast }\times A\to {\Delta }^{C}O.$ Let

Then $M$ defines the law generated by $E_M.$

Formalizing Newcombian problems

In this section, we give a mathematical definition for Newcombian problems and describe how to model Newcombian problems using fuzzy supra-POMDPs. 

Let $O$ denote a set of observations. Given a time-horizon $H\in N,$ let $O^{<H}$ denotes strings in $O$ of length less than $H.$ Let ${\Pi }_H$ denote the set of horizon-$H$ policies, i.e. maps of the form $\pi :O^{<H}\to A.$ 

Definition: Newcombian problem with horizon $H$

A Newcombian problem with horizon $H\in N$ is a map $\nu :{\Pi }_H\times O^{<H}\to \Delta O$ together with a loss function $L:(A\times O{)}^H\to [0,1].$

Intuitively speaking, given a policy and a sequence of observations, a Newcombian problem specifies some distribution that describes uncertainty about the next observation. This framework allows for a mathematical description of an environment in which there is a perfect predictor Omega and a distribution over observations that depends on the policy that Omega predicts.

Optimal policy for a Newcombian problem

Similar to how the interaction of a policy and an environment produce a distribution over destinies, a Newcombian problem $\nu$ and a policy $\pi \in {\Pi }_H$ together determine a distribution on outcomes, ${\nu }^{\pi }\in \Delta (A\times O{)}^H.$ The policy that minimizes expected loss with respect to this distribution is said to be a $\nu$-optimal policy. 

Definition: Optimal policy for a Newcombian problem

A policy $\pi \in {\Pi }_H$ is optimal for a Newcombian problem if $\pi \in {\text{argmin}}_{\pi \in {\Pi }_H}{E}_{{\nu }^{\pi }}\left[L\right]$.

If $\pi \in {\Pi }_H$ is optimal for $\nu ,$ then $E_{{\nu }^{\pi }}\left[L\right]$ is said to be the optimal loss for $\nu .$

Formalism for multiple episodes

In order to discuss learning, we consider the case of multiple episodes where an agent repeatedly encounters the Newcombian problem. 

Given some number of episodes $n>1,$ let $\Pi :O^{<nH}\to A$ denote the set of multi-episode policies. A multi-episode policy $\pi \in \Pi$ gives rise to a sequence of single-episode policies $\left\{{\pi }_k|{\pi }_k\right(o_0\dots o_m):=\pi (o_0\dots o_{kH+m}),m\le H-1{\}}_{k=0}^{n-1}\subseteq {\Pi }_H.$ 

By means of this sequence of single-episode policies, a Newcombian problem $\nu$ and a multi-episode policy together determine a distribution on outcomes over multiple episodes, which we also denote by ${\nu }^{\pi }\in \Delta (A\times O{)}^{nH}.$ 

The loss function $L:(A\times O{)}^H\to [0,1]$ can be naturally extended to multiple episodes by considering the mean loss per episode. In particular, if $n\in N$ and $h\in (A\times O{)}^{nH}$ is given by $h=a_0{o}_0\dots a_{nH-1}{o}_{nH-1},$ then the mean loss over $n$ episodes is defined as 

It is also possible to extend the loss to multiple episodes by considering the sum of the per-episode loss with a geometric time discount. In this case, the total loss is defined by 

The fuzzy supra-POMDP associated with a Newcombian problem

In this section, we describe how to model iterated Newcombian problems (i.e. repeated episodes of the problem) by a fuzzy supra-POMDP. We work in the iterated setting since this allows us to talk about learning. Examples are given in the following section.

The state space, initialization, and observation mapping

Let $\nu :{\Pi }_H\times O^{<H}\to \Delta O$ (together with $L:(A\times O{)}^H\to [0,1]$) be a Newcombian problem. Let $S={\Pi }_H\times O^{<H}.$ Informally speaking, the state always encodes both a policy and a sequence of observations.

Let the initial supracontribution over states be ${\Theta }_0={\top }_{{\Pi }_H\times \lambda }:=\overline{\text{ch}\left(\right\{{\delta }_{\pi \times \left\{\lambda \right\}}|\pi \in {\Pi }_H\}}{)}^{\downarrow }$ where $\lambda$ denotes the empty observation. This supracontribution represents complete ambiguity over the policy (and certainty over the empty observation). 

The observation mapping $B:S\to O$ simply returns the most recent observation datum from a state, i.e. $B(\pi ,o_0\dots o_n)=o_n$ for non-empty observation strings. If the observation string of the state is the empty string $\lambda ,$ then $B(\pi ,\lambda )$ may be chosen arbitrarily.

The transition suprakernel

We start with an informal description of the transition suprakernel $T:S\times A\to {\square }^{C}S,$ which is defined in three cases. In short:

1. If the action is compatible with the policy encoded by the state, then $T$ is determined by $\nu .$
2. If the action is not compatible with the policy encoded by the state, then $T$ returns ${\perp }_S.$
3. If the end of the episode is reached, then $T$ returns ${\top }_{{\Pi }_H\times \lambda }.$

To elaborate, we have the following three cases. 

1. The action is compatible with the policy encoded by the state, and the time-step is less than the horizon, i.e. the episode is not yet complete. In this case, the policy datum of the state remains the same with certainty, whereas $\nu$ determines a distribution over next observations. This distribution determines a distribution over next states. The transition suprakernel returns the downward closure of this distribution. (Here the downward closure is used simply to obtain a supracontribution.)
2. The action is not compatible with the policy encoded by the state, and the time-step is less than the horizon. This case is a logical contradiction, and thus $T$ returns ${\perp }_S.$
3. The time-step is equal to the horizon, i.e. the end of the episode has been reached. The transition suprakernel returns the initial supracontribution ${\top }_{{\Pi }_H\times \lambda }$ again, which represents complete ambiguity over the policy for the next episode (and certainty over the empty observation). 

We now formally define $T:S\times A\to {\square }^{C}S.$  Given $(\pi ,o_0\dots o_n)\in S$ such that $n<H-1,$ define $\text{pref}(\pi ,o_0\dots o_n):O\to S$ by $\text{pref}(\pi ,o_0\dots o_n)\left(q\right):=(\pi ,o_0\dots o_{n}q)$.  Namely, $\text{pref}(\pi ,o_0\dots o_n)$ appends a given observation to the prefix of observations $o_0\dots o_n$ and returns the corresponding state. Let ${\text{pref}}_{\ast }$ denote the pushforward of $\text{pref}.$

Define

Examples of Newcombian problems

In this section, we explain how to formalize various Newcombian problems using the fuzzy supra-POMDP framework. We provide the most detail for the first two examples

Newcomb's Problem

We first consider Newcomb's Problem. In this problem, there are two boxes: Box A, a transparent box that always contains $1K, and Box B, an opaque box that either contains $0 or $1M. An agent can choose to "one-box", meaning that they only take Box B, or "two-box", meaning they take both boxes. A perfect predictor Omega fills Box B with $1M if and only if Omega predicts that the agent will one-box. 

Evidential decision theory (EDT) prescribes that an agent should choose the action that maximizes the expected utility conditioned on choosing that action. Thus, EDT recommends one-boxing because choosing to one-box can be seen as evidence that Box B contains $1M. This is the case even though the correlation is spurious, i.e. choosing to one-box does not cause there to be $1M in Box B. We will see that IBDT also recommends one-boxing. In comparison to EDT, causal decision theory (CDT)^[7] prescribes that an agent should only take into account what an action causes to happen and therefore recommends two-boxing. 

Let $O=\{\lambda ,o_{\$1K},o_{\$1M},o_{\$1.001M}\}$ where $\lambda$ denotes the empty observation and the remaining observations represent the total amount of money received.

Let $A=\{a_1,a_2\},$ where $a_1$ corresponds to one-boxing and $a_2$ corresponds to two-boxing. Without loss of generality, ${\Pi }_H=\{{\pi }_1,{\pi }_2\}$ where ${\pi }_1\left(\lambda \right)=a_1$ and ${\pi }_2\left(\lambda \right)=a_2.$ 

Then $\nu :{\Pi }_H\times O^{<H}\to \Delta O$ is defined by

The loss of an episode $L:(A\times O)\to [0,1]$ is defined by

(We don't define $L\left(ao\right)$ for $o=o_{\$1.001M}$ because under this model, this observation never occurs.)

Note that $E_{{\nu }^{{\pi }_1}}\left[L\right]=1\cdot 0=0,$ and $E_{{\nu }^{{\pi }_2}}\left[L\right]=1\cdot 1=1.$ Therefore, ${\pi }_1$ is $\nu -$optimal. 

We now consider the corresponding supra-POMDP $M_{\nu }.$ The transition suprakernel is given by

Figure 5 shows the state transition graph of $M_{\nu }.$ Notably, it is not possible under $M_{\nu }$ for an agent to two-box when Box B is full (the left branch in Figure 5). This is assured by the fact that $T\left(\right({\pi }_1,\lambda ),a_2)={\perp }_S.$

The interaction of $M_{\nu }$ and ${\pi }_1$ produces a supracontribution over outcomes given by ${\Theta }_1=\{{\delta }_{a_1{o}_{\$1M}}{\}}^{\downarrow }.$ Similarly, the interaction of $M_{\nu }$ and ${\pi }_2$ produces the supracontribution ${\Theta }_2=\{{\delta }_{a_2{o}_{\$1K}}{\}}^{\downarrow }.$ 

Then the expected loss for ${\pi }_1$ in one round is 

Similarly, the expected loss for ${\pi }_2$ in one round is

From another viewpoint, the optimal (worst-case from the agent's perspective) copolicy ${\sigma }_{{\pi }_i}$ to ${\pi }_i$ initializes the state to $({\pi }_i,\lambda )$ for $i=1,2,$ i.e. ${\sigma }_{{\pi }_i}\left(\lambda \right)={\delta }_{({\pi }_i,\lambda )}.$ In other words, the policy encoded in the state chosen by the copolicy matches the policy of the agent. The law defined by this supra-POMDP is equivalent to an ordinary environment in which one-boxing results in observing a full box and two-boxing results in observing an empty box. 

We see from the above calculations that the optimal policy for $M_{\nu }$ is ${\pi }_1,$ and moreover ${\pi }_1$ achieves the $\nu$-optimal loss. This analysis holds for any number of episodes. This is significant because if a learning agent has $M^{\nu }$ in their hypothesis space, then they must converge to one-boxing if they are to achieve low regret for the iterated Newcomb's problem.

Note that for this example, we have only used what might be considered the most basic supracontributions, namely $\top ,$ $\perp ,$ and the downward closure of a single probability distribution. In the next example, we will see the full power of supracontributions. 

XOR Blackmail

In this section we describe how to use a supra-POMDP to model the XOR blackmail problem. For a more in depth discussion of XOR blackmail, see e.g. Toward Idealized Decision Theory §2.1 (Soares and Fallenstein, 2015) and Cheating Death in Damascus §2 (Levinstein and Soares, 2020). 

The problem is given as follows. Suppose there is a 1% probability that an agent's house may have a termite infestation that would cause $1M in damages. A blackmailer can predict the agent and also knows whether or not there is an infestation. The blackmailer sends a letter stating that exactly one of the following is true, if and only if the letter is truthful:

1. There are no termites, and you will pay $1K, or
2. There are termites, and you will not pay.

The agent can then accept or reject the blackmail. Note that as stated, the probability of blackmail depends on the agent's policy. Because policies are encoded in the state space of the associated supra-POMDP, we are able to model this. EDT recommends accepting the blackmail because accepting blackmail is evidence that there is not an infestation, even though this correlation is spurious (i.e. accepting the blackmail does not causally influence whether or not there is an infestation). On the other hand, CDT recommends rejecting the blackmail. Thus we see that these two decision theories are split across the two examples that we have seen so far and neither always recommends an optimal action. We now see that IBDT does recommend the optimal action again. 

Let $O=\{\lambda ,o_B,o_{NB},o_{\$0},o_{-\$\text{1K}},o_{-\$\text{1M}}\},$ where $\lambda$ denotes the empty observation, $o_B$ represents receiving the blackmail, $o_{NB}$ represents not receiving the blackmail, and the remaining observations represent the various monetary outcomes.

Let $A=\{a_a,a_r\},$ where $a_a$ corresponds to accepting the blackmail and $a_r$ corresponds to rejecting the blackmail. Without loss of generality, ${\Pi }_H=\{{\pi }_a,{\pi }_r\}$ where ${\pi }_a:(\dots o_B)=a_a$ and  ${\pi }_r(\dots o_B)=a_r.$ 

Interpreting the statement of the problem, we define $\nu :{\Pi }_H\times O^{<H}\to \Delta O$ as follows:

We normalize in order to define the loss of an episode $L:(A\times O{)}^H\to [0,1]$ by

Note that $E_{{\nu }^{{\pi }_a}}\left[L\right]=0.99\cdot 0.001+0.01\cdot 1,$ whereas $E_{{\nu }^{{\pi }_r}}\left[L\right]=0.99\cdot 0+0.01\cdot 1.$ Therefore ${\pi }_r$ is $\nu -$optimal. 

We now consider the corresponding supra-POMDP $M_{\nu }.$ The state transitions of $M_{\nu }$ are summarized in Figure 6. We first define the transition suprakernel on ${\Pi }_H\times \lambda .$ Using $\nu ,$ we have

We now consider the next level of the supra-POMDP. Since ${\pi }_a\left(o_B\right)=a_a,$

Here we see that when the action is $a_a$, which is consistent with the policy of the state ${\pi }_a$, the transition kernel returns the downward closure of a distribution specified by $\nu .$ On the other hand, when the action is $a_r$, which is not consistent with ${\pi }_a$, the transition kernel returns ${\perp }_S$.

The action does not matter when there is no blackmail (i.e. both actions are consistent with the policy), so

A similar analysis for ${\pi }_r$ yields

Then on the final level: for all $s\in \left\{{\pi }_a\right\}\times \{o_B{o}_{-\$1K},o_{NB}{o}_{-\$1M}\}\cup \left\{{\pi }_r\right\}\times \{o_{NB}{o}_{\$0},o_B{o}_{-\$1M}\},$ define 

We now consider the expected loss of each policy for $M_{\nu }.$ The interaction of $M_{\nu }$ and ${\pi }_a$ produces a supracontribution over outcomes given by $\Theta =\text{ch}\{{\theta }_0,{\theta }_1{\}}^{\downarrow }$ where

Here, ${\theta }_0$ arises from the interaction of ${\pi }_a$ with the branch starting with state $({\pi }_a,\lambda ).$ We have a probability distribution in this case because ${\pi }_a$ is always consistent with itself, which is the policy encoded in the states of this branch. On the other hand, the contribution ${\theta }_1$ arises from the interaction of ${\pi }_a$ with the branch starting with state $({\pi }_r,\lambda ).$ In the case of blackmail, ${\pi }_a$ and ${\pi }_r$ disagree on the action and thus a probability mass of 0.01 is lost on this branch. 

Therefore, the expected loss for ${\pi }_a$ in one round is given by

Another way to view this calculation is that the optimal $M_{\nu }$-copolicy $\sigma$ initializes the state to $({\pi }_a,\lambda ),$ meaning $\sigma \left(\lambda \right)={\delta }_{({\pi }_a,\lambda )}.$

By a similar calculation,

Therefore, the optimal policy for $M_{\nu }$ is also ${\pi }_r$, i.e. under this formulation it is optimal to reject the blackmail. This analysis holds for any number of episodes. Moreover, the optimal loss for $M_{\nu }$ is equal to the optimal loss for $\nu .$ This is significant because if a learning agent has $M_{\nu }$ in their hypothesis space, then they must converge to rejecting the blackmail if they are to achieve low regret for the iterated Newcombian problem.

Counterfactual Mugging

We now consider the problem of counterfactual mugging. In this problem, a perfect predictor (the "mugger") flips a coin. If the outcome is heads, the mugger asks the agent for $100, at which point they can decide to pay or not pay. Otherwise, they give the agent $10K if and only if they predict the agent would have paid the $100 if the outcome was heads.

Both CDT and EDT recommend not paying, and yet we will see that IBDT recommends to pay the mugger. 

Let $O=\{\lambda ,o_H,o_T,o_{\$10K},o_{-\$100},o_{\$0}\},$ where $o_H$ represents heads, $o_T$ represents tails, and the remaining (non-empty) observations represent the various monetary outcomes. Let $A=\{a_p,a_{np}\},$ where $a_p$ represents paying the mugger and $a_{np}$ represents not paying the mugger. Without loss of generality, ${\Pi }_H=\{{\pi }_p,{\pi }_{np}\}$ where ${\pi }_p(\dots o_H)=a_p$ and  ${\pi }_{np}(\dots o_H)=a_{np}.$

Let $\alpha :=1-\frac{100}{10,100}$. We normalize^[8] to define the loss $L:(A\times O{)}^H\to [0,1]$ of an episode by 

Note that $E_{{\nu }^{{\pi }_p}}\left[L\right]=0.5\left(1\right)+0.5\left(0\right)=0.5,$ whereas $E_{{\nu }^{{\pi }_{np}}}\left[L\right]=0.5\left(\alpha \right)+0.5\left(\alpha \right)=\alpha .$ Therefore, ${\pi }_p$ is $\nu$-optimal. 

The state transitions of $M_{\nu }$ are shown in Figure 7.

We have

whereas

Therefore, the optimal policy for $M^{\nu }$ is also ${\pi }_p$, i.e. under this formulation it is optimal to pay the mugger.

Transparent Newcomb's Problem

We now consider Transparent Newcomb's Problem. In this problem, both boxes of the original problem are transparent. We consider three versions. See Figure 11 in the next section for a summary of the decision theory recommendations. 

Empty-box dependent 

In the empty-box dependent version, a perfect predictor Omega leaves Box B empty if and only if Omega predicts that the agent will two-box upon seeing that Box B is empty.

Let $O=\{\lambda ,o_E,o_F,o_{\$1M},o_{\$1K},o_{\$1.001M}\}.$ Here $o_E$ corresponds to observing an empty box and $o_F$ corresponds to observing a full box. Let $A=\{a_1,a_2\},$ where $a_1$ corresponds to one-boxing and $a_2$ corresponds to two-boxing.

Without loss of generality, ${\Pi }_H=\{{\pi }_{1,1},{\pi }_{1,2},{\pi }_{2,1},{\pi }_{2,2}\}$ where ${\pi }_{i,j}(\dots o_E)=a_i$ and ${\pi }_{i,j}(\dots o_F)=a_j$ for $i,j\in \{1,2\}.$ Namely, the policies are distinguished by the action chosen upon observing an empty or full box. 

Let $\alpha :=1-\frac{1,000,000}{1,001,000}$. Define $L:(A\times O{)}^H\to [0,1]$ by

The state transition graph of the supra-POMDP $M_{\nu }$ representing this problem is shown in Figure 8.

We now consider the expected loss in one round for each policy interacting with $M_{\nu }.$ Similarly to the original version of Newcomb's problem, the optimal copolicy to a policy ${\pi }_{i,j}$ initializes the state to $({\pi }_{i,j},\lambda )$, meaning the policy encoded in the state chosen by the copolicy matches the true policy of the agent. 

We have

Therefore, the optimal policy for $M_{\nu }$ is ${\pi }_{1,2},$ meaning it is optimal to one-box upon observing an empty box and to two-box upon seeing a full box. Note that ${\pi }_{1,2}$ is also the $\nu$-optimal policy.

Full-box dependent

In the full-box dependent version, Omega (a perfect predictor) puts $1M in Box B if and only if Omega predicts that the agent will one-box upon seeing that Box B is full. This example does not satisfy pseudocausality (discussed below), and therefore we will see that there is an inconsistency between the optimal policies for the supra-POMDP $M_{\nu }$ and the Newcombian problem $\nu .$

Let $O=\{\lambda ,o_E,o_F,o_{\$1M},o_{\$1K},o_{\$0}\},$ and $A=\{a_1,a_2\}.$ Without loss of generality, we again have ${\Pi }_H=\{{\pi }_{1,1},{\pi }_{1,2},{\pi }_{2,1},{\pi }_{2,2}\}$ where ${\pi }_{i,j}(\dots o_E)=a_i$ and ${\pi }_{i,j}(\dots o_F)=a_j$ for $i,j\in \{1,2\}.$