abramdemski

• abramdemski 15 Sep 2019 7:22 UTC

  2 points

  in reply to: rk's comment on: Do Suffi­ciently Ad­vanced Agents Use Logic?

  Back­wards, thanks!

• abramdemski 14 Sep 2019 22:03 UTC

  2 points

  AF

  in reply to: Vanessa Kosoy's comment on: For­mal­is­ing de­ci­sion the­ory is hard

  I am not sure what you mean by “meets the LIC or similar” in this con­text. If we con­sider a pre­dic­tor which is a learn­ing al­gorithm in it­self (i.e., it pre­dicts by learn­ing from the agent’s past choices),

  Yeah, that’s what I meant.

  , then the agent will con­verge to one-box­ing. This is be­cause a weak pre­dic­tor will be fully in­side the agent’s prior, so the agent will know that one-box­ing for long enough will cause the pre­dic­tor to fill the box.

  Sup­pose the in­ter­val be­tween en­coun­ters with the pre­dic­tor is long enough that, due to the agent’s tem­po­ral dis­count­ing, the im­me­di­ate re­ward of two-box­ing out­weighs the later gains which one-box­ing pro­vides. In any spe­cific en­counter with the pre­dic­tor, the agent may pre­fer to two-box, but pre­fer to have been the sort of agent who pre­dictably one-boxes, and also prefer­ring to pre-com­mit to one-box on the next ex­am­ple if a com­mit­ment mechanism ex­ists. (This sce­nario also re­quires a care­fully tuned strength for the pre­dic­tor, of course.)

  But I wasn’t sure this would be the re­sult for your agent, since you de­scribed the agent us­ing the hy­poth­e­sis which gives the best pic­ture about achiev­able util­ity.

  As I dis­cussed in Do Suffi­ciently Ad­vanced Agents Use Logic, what I tend to think about is the case where the agent doesn’t liter­ally en­counter the pre­dic­tor re­peat­edly in its phys­i­cal his­tory. In­stead, the agent must learn what strat­egy to use by rea­son­ing about similar (but “smaller”) sce­nar­ios. But we can get the same effect by as­sum­ing the tem­po­ral dis­count­ing is steep enough, as above.

  I was never con­vinced that “log­i­cal ASP” is a “fair” prob­lem. I once joked with Scott that we can con­sider a “pre­dic­tor” that is just the sin­gle line of code “re­turn DEFECT” but in the com­ments it says “I am defect­ing only be­cause I know you will defect.” It was a joke, but it was half-se­ri­ous. The no­tion of “weak pre­dic­tor” taken to the limit leads to ab­sur­dity, and if you don’t take it to the limit it might still lead to ab­sur­dity. Log­i­cal in­duc­tors in one way to try spec­i­fy­ing a “weak pre­dic­tor”, but I am not con­vinced that set­tings in which logic is in­serted ad hoc should be made into desider­ata.

  Yeah, it is clear that there has to be a case where the pre­dic­tor is so weak that the agent should not care. I’m fine with drop­ping the purely log­i­cal cases as desider­ata in fa­vor of the learn­ing-the­o­retic ver­sions. But, the abil­ity to con­struct analo­gous prob­lems for logic and for learn­ing the­ory is no­table. Pay­ing at­ten­tion to that anal­ogy more gen­er­ally seems like a good idea.

  I am not sure we need an ar­bi­trary cut­off. There might be a good solu­tion where the agent can dy­nam­i­cally choose any finite cut­off.

  Yeah, I guess we can do a va­ri­ety of things:

  • Nam­ing a time limit for the com­mit­ment.

  • Nam­ing a time at which a time limit for the com­mit­ment will be named.

  • Nam­ing an or­di­nal (in some or­di­nal no­ta­tion), so that a smaller or­di­nal must be named ev­ery time-step, un­til a smaller or­di­nal can­not be named, at which point the com­mit­ment runs out

  I sus­pect I want to eval­u­ate a com­mit­ment scheme by ask­ing whether it helps achieve a nice re­gret-bound no­tion, rather than defin­ing the re­gret no­tion by eval­u­at­ing re­gret-with-re­spect-to-mak­ing-com­mit­ments.

  Think­ing about LI policy se­lec­tion where we choose a slow-grow­ing func­tion f(n) which de­ter­mines how long we think be­fore we choose the policy to fol­low on day n –– there’s this weird trade-off be­tween how (ap­par­ently) “good” the up­date­less­ness is vs how long it takes to be any good at all. I’m fine with no­tions of ra­tio­nal­ity be­ing pa­ram­e­ter­ized by an or­di­nal or some such if it’s just a choose-the-largest-num­ber game. But in this case, choos­ing too slow-grow­ing a func­tion makes you worse off; so the fact that the ra­tio­nal­ity prin­ci­ple is pa­ram­e­ter­ized (by the slow-grow­ing func­tion) is prob­le­matic. Choos­ing a com­mit­ment scheme seems similar.

  So it would be nice to have a ra­tio­nal­ity no­tion which clar­ified this situ­a­tion.

  My main con­cern here is: the case for em­piri­cal up­date­less­ness seems strong in re­al­iz­able situ­a­tions where the prior is mean­ingful. Things aren’t as nice in the non-re­al­iz­able cases such as log­i­cal un­cer­tainty. But it doesn’t make sense to aban­don up­date­less prin­ci­ples al­to­gether be­cause of this!

• abramdemski 14 Sep 2019 1:43 UTC

  17 points

  AF

  in reply to: abramdemski's comment on: A Cri­tique of Func­tional De­ci­sion Theory

  Re­sponse to Sec­tion IV:

  FDT fails to get the an­swer Y&S want in most in­stances of the core ex­am­ple that’s sup­posed to mo­ti­vate it

  I am ba­si­cally sym­pa­thetic to this con­cern: I think there’s a clear in­tu­ition that FDT is 2-box­ing more than we would like (and a clear for­mal pic­ture, in toy for­mal­isms which show FDT-ish DTs failing on Agent Si­mu­lates Pre­dic­tor prob­lems).

  Of course, it all de­pends on how log­i­cal coun­ter­fac­tu­als are sup­posed to work. From a de­sign per­spec­tive, I’m happy to take challenges like this as ex­tra re­quire­ments for the be­hav­ior of log­i­cal coun­ter­fac­tu­als, rather than ob­jec­tions to the whole pro­ject. I in­tu­itively think there is a no­tion of log­i­cal coun­ter­fac­tual which fails in this re­spect, but, this does not mean there isn’t some other no­tion which suc­ceeds. Per­haps we can solve the easy prob­lem of one-box­ing with a strong pre­dic­tor first, and then look for ways to one-box more gen­er­ally (and in fact, this is what we’ve done—one-box­ing with a strong pre­dic­tor is not so difficult).

  How­ever, I do want to add that when Omega uses very weak pre­dic­tion meth­ods such as the ex­am­ples given, it is not so clear that we want to one-box. Will is pre­sum­ing that Y&S sim­ply want to one-box in any New­comb prob­lem. How­ever, we could make a dis­tinc­tion be­tween ev­i­den­tial New­comb prob­lems and func­tional New­comb prob­lems. Y&S already state that they con­sider some things to be func­tional New­comb prob­lems de­spite them not be­ing ev­i­den­tial New­comb prob­lems (such as trans­par­ent New­comb). It stands to rea­son that there would be some ev­i­den­tial New­comb prob­lems which are not func­tional New­comb prob­lems, as well, and that Y&S would pre­fer not to one-box in such cases.

  How­ever, the pre­dic­tor needn’t be run­ning your al­gorithm, or have any­thing like a rep­re­sen­ta­tion of that al­gorithm, in or­der to pre­dict whether you’ll one box or two-box. Per­haps the Scots tend to one-box, whereas the English tend to two-box.

  In this ex­am­ple, it seems quite plau­si­ble that there’s a (logico-causal) rea­son for the reg­u­lar­ity, so that in the log­i­cal coun­ter­fac­tual where you act differ­ently, your refer­ence class also acts some­what differ­ently. Say you’re Scot­tish, and 10% of Scots read a par­tic­u­lar fairy tale grow­ing up, and this is con­nected with why you two-box. Then in the coun­ter­fac­tual in which you one-box, it is quite pos­si­ble that those 10% also one-box. Of course, this greatly weak­ens the con­nec­tion be­tween Omega’s pre­dic­tion and your ac­tion; per­haps the change of 10% is not enough to tip the scales in Omega’s pre­dic­tion.

  But, with­out any ac­count of Y&S’s no­tion of sub­junc­tive coun­ter­fac­tu­als, we just have no way of as­sess­ing whether that’s true or not. Y&S note that spec­i­fy­ing an ac­count of their no­tion of coun­ter­fac­tu­als is an ‘open prob­lem,’ but the prob­lem is much deeper than that. Without such an ac­count, it be­comes com­pletely in­de­ter­mi­nate what fol­lows from FDT, even in the core ex­am­ples that are sup­posed to mo­ti­vate it — and that makes FDT not a new de­ci­sion the­ory so much as a promis­sory note.

  In the TDT doc­u­ment, Eliezer ad­dresses this con­cern by point­ing out that CDT also takes a de­scrip­tion of the causal struc­ture of a prob­lem as given, beg­ging the ques­tion of how we learn causal coun­ter­fac­tu­als. In this re­gard, FDT and CDT are on the same level of promis­sory-note-ness.

  It might, of course, be taken as much more plau­si­ble that a tech­nique of learn­ing the phys­i­cal-causal struc­ture can be pro­vided, in con­trast to a tech­nique which learns the log­i­cal-coun­ter­fac­tual struc­ture.

  I want to in­ject a lit­tle doubt about which is eas­ier. If a robot is in­ter­act­ing with an ex­act simu­la­tion of it­self (in an iter­ated pris­oner’s dilemma, say), won’t it be eas­ier to in­fer that it di­rectly con­trols the copy than it is to figure out that the two are run­ning on differ­ent com­put­ers and thus causally in­de­pen­dent?

  Put more gen­er­ally: log­i­cal un­cer­tainty has to be han­dled one way or an­other; it can­not be en­tirely put aside. Ex­ist­ing meth­ods of test­ing causal­ity are not de­signed to deal with it. It stands to rea­son that such meth­ods ap­plied naively to cases in­clud­ing log­i­cal un­cer­tainty would treat such un­cer­tainty like phys­i­cal un­cer­tainty, and there­fore tend to pro­duce log­i­cal-coun­ter­fac­tual struc­ture. This would not nec­es­sar­ily be very good for FDT pur­poses, be­ing the re­sult of un­prin­ci­pled ac­ci­dent—and the con­cern for FDT’s coun­ter­fac­tu­als is that there may be no prin­ci­pled foun­da­tion. Still, I tend to think that other de­ci­sion the­o­ries merely brush the prob­lem un­der the rug, and ac­tu­ally have to deal with log­i­cal coun­ter­fac­tu­als one way or an­other.

  In­deed, on the most plau­si­ble ways of cash­ing this out, it doesn’t give the con­clu­sions that Y&S would want. If I imag­ine the clos­est world in which 6288 + 1048 = 7336 is false (Y&S’s ex­am­ple), I imag­ine a world with laws of na­ture rad­i­cally un­like ours — be­cause the laws of na­ture rely, fun­da­men­tally, on the truths of math­e­mat­ics, and if one math­e­mat­i­cal truth is false then ei­ther (i) math­e­mat­ics as a whole must be rad­i­cally differ­ent, or (ii) all math­e­mat­i­cal propo­si­tions are true be­cause it is sim­ple to prove a con­tra­dic­tion and ev­ery propo­si­tions fol­lows from a con­tra­dic­tion.

  To this I can only say again that FDT’s prob­lem of defin­ing coun­ter­fac­tu­als seems not so differ­ent to me from CDT’s prob­lem. A causal de­ci­sion the­o­rist should be able to work in a math­e­mat­i­cal uni­verse; in­deed, this seems rather con­sis­tent with the on­tol­ogy of mod­ern sci­ence, though not forced by it. I find it im­plau­si­ble that a CDT ad­vo­cate should have to deny Teg­mark’s math­e­mat­i­cal uni­verse hy­poth­e­sis, or should break down and be un­able to make de­ci­sions un­der the sup­po­si­tion. So, phys­i­cal coun­ter­fac­tu­als seem like they have to be at least ca­pa­ble of be­ing log­i­cal coun­ter­fac­tu­als (per­haps a differ­ent sort of log­i­cal coun­ter­fac­tual than FDT would use, since phys­i­cal coun­ter­fac­tu­als are sup­posed to give cer­tain differ­ent an­swers, but a sort of log­i­cal coun­ter­fac­tual nonethe­less).

  (But this con­clu­sion is far from ob­vi­ous, and I don’t ex­pect ready agree­ment that CDT has to deal with this.)

• abramdemski 14 Sep 2019 0:48 UTC

  18 points

  AF

  in reply to: abramdemski's comment on: A Cri­tique of Func­tional De­ci­sion Theory

  Re­sponse to Sec­tion VIII:

  An al­ter­na­tive ap­proaches that cap­tures the spirit of FDT’s aims

  I’m some­what con­fused about how you can buy FDT as far as you seem to buy it in this sec­tion, while also claiming not to un­der­stand FDT to the point of say­ing there is no sen­si­ble per­spec­tive at all in which it can be said to achieve higher util­ity. From the per­spec­tive in this sec­tion, it seems you can straight­for­wardly in­ter­pret FDT’s no­tion of ex­pected util­ity max­i­miza­tion via an eval­u­a­tive fo­cal point such as “the out­put of the al­gorithm given these in­puts”.

  This eval­u­a­tive fo­cal point ad­dresses the con­cern you raise about how bounded abil­ity to im­ple­ment de­ci­sion pro­ce­dures in­ter­acts with a “best de­ci­sion pro­ce­dure” eval­u­a­tive fo­cal point (mak­ing it de­part from FDT’s recom­men­da­tions in so far as the agent can’t man­age to act like FDT), since those con­cerns don’t arise (at least not so clearly) when we con­sider what FDT would recom­mend for the re­sponse to one situ­a­tion in par­tic­u­lar. On the other hand, we also can make sense of the no­tion that tak­ing the bomb is best, since (ac­cord­ing to both global-CDT and global-EDT) it is best for an al­gorithm to out­put “left” when given the in­puts of the bomb prob­lem (in that it gives us the best news about how that agent would do in bomb prob­lems, and causes the agent to do well when put in bomb prob­lems, in so far as a causal in­ter­ven­tion on the out­put of the al­gorithm also af­fects a pre­dic­tor run­ning the same al­gorithm).

• abramdemski 14 Sep 2019 0:39 UTC

  17 points

  AF

  in reply to: abramdemski's comment on: A Cri­tique of Func­tional De­ci­sion Theory

  Re­sponses to Sec­tions V and VI:

  Im­plau­si­ble discontinuities

  I’m puz­zled by this con­cern. Is the doc­trine of ex­pected util­ity plagued by a cor­re­spond­ing ‘im­plau­si­ble dis­con­ti­nu­ity’ prob­lem be­cause if ac­tion 1 has ex­pected value .999 and ac­tion 2 has ex­pected value 1, then you should take ac­tion 2, but a very small change could mean you should take ac­tion 1? Is CDT plagued by an im­plau­si­ble-dis­con­ti­nu­ity prob­lem be­cause two prob­lems which EDT would treat as the same will differ in causal ex­pected value, and there must be some in-be­tween prob­lem where un­cer­tainty about the causal struc­ture bal­ances be­tween the two op­tions, so CDT’s recom­men­da­tion im­plau­si­bly makes a sharp shift when the un­cer­tainty is jig­gled a lit­tle? Can’t we similarly bog­gle at the im­plau­si­bil­ity that a tiny change in the phys­i­cal struc­ture of a prob­lem should make such a large differ­ence in the causal struc­ture so as to change CDT’s recom­men­da­tion? (For ex­am­ple, the tiny change can be a small ad­just­ment to the coin which de­ter­mines which of two causal struc­tures will be in play, with no over­all change in the ev­i­den­tial struc­ture.)

  It seems like what you find im­plau­si­ble about FDT here has noth­ing to do with dis­con­ti­nu­ity, un­less you find CDT and EDT similarly im­plau­si­ble.

  FDT is deeply indeterminate

  This is ob­vi­ously a big challenge for FDT; we don’t know what log­i­cal coun­ter­fac­tu­als look like, and in­vok­ing them is prob­le­matic un­til we do.

  How­ever, I can point to some toy mod­els of FDT which lend cre­dence to the idea that there’s some­thing there. The most in­ter­est­ing may be MUDT (see the “modal UDT” sec­tion of this sum­mary post). This de­ci­sion the­ory uses the no­tion of “pos­si­ble” from the modal logic of prov­abil­ity, so that de­spite be­ing a de­ter­minis­tic agent and there­fore only tak­ing one par­tic­u­lar ac­tion in fact, agents have a well-defined pos­si­ble-world struc­ture to con­sider in mak­ing de­ci­sions, de­rived from what they can prove.

  I have a post planned that fo­cuses on a differ­ent toy model, sin­gle-player ex­ten­sive-form games. This has the ad­van­tage of be­ing only as ex­otic as stan­dard game the­ory.

  In both of these cases, FDT can be well-speci­fied (at least, to the ex­tent we’re satis­fied with call­ing the toy DTs ex­am­ples of FDT—which is a bit awk­ward, since FDT is kind of a weird um­brella term for sev­eral pos­si­ble DTs, but also kind of speci­fi­cally sup­posed to use func­tional graphs, which MUDT doesn’t use).

  It bears men­tion­ing that a Bayesian already re­gards the prob­a­bil­ity dis­tri­bu­tion rep­re­sent­ing a prob­lem to be deeply in­de­ter­mi­nate, so this seems less bad if you start from such a per­spec­tive. Log­i­cal coun­ter­fac­tu­als can similarly be thought of as sub­jec­tive ob­jects, rather than some ob­jec­tive fact which we have to un­cover in or­der to know what FDT does.

  On the other hand, greater in­de­ter­mi­nacy is still worse; just be­cause we already have lots of de­grees of free­dom to mess our­selves up with doesn’t mean we hap­pily ac­cept even more.

  And in gen­eral, it seems to me, there’s no fact of the mat­ter about which al­gorithm a phys­i­cal pro­cess is im­ple­ment­ing in the ab­sence of a par­tic­u­lar in­ter­pre­ta­tion of the in­puts and out­puts of that phys­i­cal pro­cess.

  Part of the rea­son that I’m happy for FDT to need such a fact is that I think I need such a fact any­way, in or­der to deal with an­thropic un­cer­tainty, and other is­sues.

  If you don’t think there’s such a fact, then you can’t take a com­pu­ta­tion­al­ist per­spec­tive on the­ory of mind—in which case, I won­der what po­si­tion you take on ques­tions such as con­scious­ness. Ob­vi­ously this leads to a num­ber of ques­tions which are quite aside from the point at hand, but I would per­son­ally think that ques­tions such as whether an or­ganism is ex­pe­rienc­ing suffer­ing have to do with what com­pu­ta­tions are oc­cur­ring. This ul­ti­mately cashes out to phys­i­cal facts, yes, but it seems as if suffer­ing should be a fun­da­men­tally com­pu­ta­tional fact which cashes out in terms of phys­i­cal facts only in a sub­strate-in­de­pen­dent way (ie, the phys­i­cal facts of im­por­tance are pre­cisely those which per­tain to the ques­tion of which com­pu­ta­tion is run­ning).

  But al­most all ac­counts of com­pu­ta­tion in phys­i­cal pro­cesses have the is­sue that very many phys­i­cal pro­cesses are run­ning very many differ­ent al­gorithms, all at the same time.

  In­deed, I think this is one of the main ob­sta­cles to a satis­fy­ing ac­count—a suc­cess­ful ac­count should not have this prop­erty.

• abramdemski 14 Sep 2019 0:39 UTC

  15 points

  AF

  in reply to: abramdemski's comment on: A Cri­tique of Func­tional De­ci­sion Theory

  Re­sponse to Sec­tion VII:

  Assess­ing by how well the de­ci­sion-maker does in pos­si­ble wor­lds that she isn’t in fact in doesn’t seem a com­pel­ling crite­rion (and EDT and CDT could both do well by that crite­rion, too, de­pend­ing on which pos­si­ble wor­lds one is al­lowed to pick).

  You make the claim that EDT and CDT can claim op­ti­mal­ity in ex­actly the same way that FDT can, here, but I think the ar­gu­ments are im­por­tantly not sym­met­ric. CDT and EDT are op­ti­mal ac­cord­ing to their own op­ti­mal­ity no­tions, but given the choice to im­ple­ment differ­ent de­ci­sion pro­ce­dures on later prob­lems, both the CDT and EDT op­ti­mal­ity no­tions would en­dorse se­lect­ing FDT over them­selves in many of the prob­lems men­tioned in the pa­per, whereas FDT will en­dorse it­self.

  Most of this sec­tion seems to me to be an ar­gu­ment to make care­ful level dis­tinc­tions, in an at­tempt to avoid the level-cross­ing ar­gu­ment which is FDT’s main ap­peal. Cer­tainly, FDTers such as my­self will of­ten use lan­guage which con­fuses the var­i­ous lev­els, since we take a po­si­tion which says they should be con­fus­able—the best de­ci­sion pro­ce­dures should fol­low the best poli­cies, which should take the best ac­tions. But mak­ing care­ful level dis­tinc­tions does not block the level-cross­ing ar­gu­ment, it only clar­ifies it. FDT may not be the only “con­sis­tent fixed-point of nor­ma­tivity” (to the ex­tent that it even is that), but CDT and EDT are clearly not that.

  Fourth, ar­gu­ing that FDT does best in a class of ‘fair’ prob­lems, with­out be­ing able to define what that class is or why it’s in­ter­est­ing, is a pretty weak ar­gu­ment.

  I ba­si­cally agree that the FDT pa­per dropped the ball here, in that it could have given a toy set­ting in which ‘fair’ is rigor­ously defined (in a pretty stan­dard game-the­o­retic set­ting) and FDT has the claimed op­ti­mal­ity no­tion. I hope my longer writeup can make such a set­ting clear.

  Briefly: my in­ter­pre­ta­tion of the “FDT does bet­ter” claim in the FDT pa­per is that FDT is sup­posed to take UDT-op­ti­mal ac­tions. To the ex­tent that it doesn’t take UDT-op­ti­mal ac­tions, I mostly don’t en­dorse the claim that it does bet­ter (though I plan to note in a fol­low-up post an al­ter­nate view in which the FDT no­tion of op­ti­mal­ity may be bet­ter).

  The toy set­ting I have in mind that makes “UDT-op­ti­mal” com­pletely well-defined is ac­tu­ally fairly gen­eral. The idea is that if we can rep­re­sent a de­ci­sion prob­lem as a (sin­gle-player) ex­ten­sive-form game, UDT is just the idea of throw­ing out the re­quire­ment of sub­game-op­ti­mal­ity. In other words, we don’t even need a no­tion of “fair­ness” in the set­ting of ex­ten­sive-form games—the set­ting isn’t rich enough to rep­re­sent any “un­fair” prob­lems. Yet it is a pretty rich set­ting.

  This ob­ser­va­tion was already made here: https://​​www.less­wrong.com/​​posts/​​W4sDWwGZ4puRBXMEZ/​​sin­gle-player-ex­ten­sive-form-games-as-a-model-of-udt. Note that there are some con­cerns in the com­ments. I think the con­cerns make sense, and I’m not quite sure how I want to ad­dress them, but I also don’t think they’re damn­ing to the toy model.

  The FDT pa­per may have left out this model out of a de­sire for greater gen­er­al­ity, which I do think is an im­por­tant goal—from my per­spec­tive, it makes sense not to re­duce things to the toy model in which ev­ery­thing works out nicely.

• abramdemski 14 Sep 2019 0:35 UTC

  23 points

  AF

  on: A Cri­tique of Func­tional De­ci­sion Theory

  Here are some (very lightly ed­ited) com­ments I left on Will’s draft of this post. (See also my top-level re­sponse.)

  Re­sponses to Sec­tions II and III:

  I’m not claiming that it’s clear what this means. E.g. see here, sec­ond bul­let point, ar­gu­ing there can be no such prob­a­bil­ity func­tion, be­cause any prob­a­bil­ity func­tion re­quires cer­tainty in log­i­cal facts and all their en­tail­ments.

  This point shows the in­ter­twin­ing of log­i­cal coun­ter­fac­tu­als (coun­ter­pos­si­bles) and log­i­cal un­cer­tainty. I take log­i­cal in­duc­tion to rep­re­sent sig­nifi­cant progress gen­er­al­iz­ing prob­a­bil­ity the­ory to the case of log­i­cal un­cer­tainty, ie, ob­jects which have many of the virtues of prob­a­bil­ity func­tions while not re­quiring cer­tainty about en­tail­ment of known facts. So, we can sub­stan­tially re­ply to this ob­jec­tion.

  How­ever, re­ply­ing to this ob­jec­tion does not nec­es­sar­ily mean we can define log­i­cal coun­ter­fac­tu­als as we would want. So far we have only been able to use log­i­cal in­duc­tion to spec­ify a kind of “log­i­cally un­cer­tain ev­i­den­tial con­di­tional”. (IE, some­thing closer in spirit to EDT, which does be­have more like FDT in some prob­lems but not in gen­eral.)

  I want to em­pha­size that I agree that spec­i­fy­ing what log­i­cal coun­ter­fac­tu­als are is a grave difficulty, so grave as to seem (to me, at pre­sent) to be damn­ing, pro­vided one can avoid the difficulty in some other ap­proach. How­ever, I don’t ac­tu­ally think that the difficulty can be avoided in any other ap­proach! I think CDT ul­ti­mately has to grap­ple with the ques­tion as well, be­cause physics is math, and so phys­i­cal coun­ter­fac­tu­als are ul­ti­mately math­e­mat­i­cal coun­ter­fac­tu­als. Even EDT has to grap­ple with this prob­lem, ul­ti­mately, due to the need to han­dle cases where one’s own ac­tion can be log­i­cally known. (Or provide a con­vinc­ing ar­gu­ment that such cases can­not arise, even for an agent which is com­putable.)

  Guaran­teed Pay­offs: In con­di­tions of cer­tainty — that is, when the de­ci­sion-maker has no un­cer­tainty about what state of na­ture she is in, and no un­cer­tainty about the util­ity pay­off of each ac­tion is — the de­ci­sion-maker should choose the ac­tion that max­imises util­ity.

  (Obli­ga­tory re­mark that what max­i­mizes util­ity is part of what’s at is­sue here, and for pre­cisely this rea­son, an FDTist could re­spond that it’s CDT and EDT which fail in the Bomb ex­am­ple—by failing to max­i­mize the a pri­ori ex­pected util­ity of the ac­tion taken.)

  FDT would dis­agree with this prin­ci­ple in gen­eral, since full cer­tainty im­plies cer­tainty about one’s ac­tion, and the util­ity to be re­ceived, as well as ev­ery­thing else. How­ever, I think we can set that aside and say there’s a ver­sion of FDT which would agree with this prin­ci­ple in terms of prior un­cer­tainty. It seems cases like Bomb can­not be set up with­out ei­ther in­vok­ing prior un­cer­tainty (tak­ing the form of the pre­dic­tor’s failure rate) or bring­ing the ques­tion of how to deal with log­i­cally im­pos­si­ble de­ci­sions to the fore­front (if we con­sider the case of a perfect pre­dic­tor).

  Why should prior un­cer­tainty be im­por­tant, in cases of pos­te­rior cer­tainty? Be­cause of the prior-op­ti­mal­ity no­tion (in which a de­ci­sion the­ory is judged on a de­ci­sion prob­lem based on the util­ity re­ceived in ex­pec­ta­tion ac­cord­ing to the prior prob­a­bil­ity which defines the de­ci­sion prob­lem).

  Prior-op­ti­mal­ity con­sid­ers the guaran­teed-pay­off ob­jec­tion to be very similar to ob­ject­ing to a gam­bling strat­egy by point­ing out that the gam­bling strat­egy some­times loses. In Bomb, the prob­lem clearly stipu­lates that an agent who fol­lows the FDT recom­men­da­tion has a trillion trillion to one odds of do­ing bet­ter than an agent who fol­lows the CDT/​EDT recom­men­da­tion. Com­plain­ing about the one-in-a-trillion-trillion chance that you get the bomb while be­ing the sort of agent who takes the bomb is, to an FDT-the­o­rist, like a gam­bler who has just lost a trillion-trillion-to-one bet com­plain­ing that the bet doesn’t look so ra­tio­nal now that the out­come is known with cer­tainty to be the one-in-a-trillion-trillion case where the bet didn’t pay well.

  The right ac­tion, ac­cord­ing to FDT, is to take Left, in the full knowl­edge that as a re­sult you will slowly burn to death. Why? Be­cause, us­ing Y&S’s coun­ter­fac­tu­als, if your al­gorithm were to out­put ‘Left’, then it would also have out­putted ‘Left’ when the pre­dic­tor made the simu­la­tion of you, and there would be no bomb in the box, and you could save your­self $100 by tak­ing Left.

  And why, on your ac­count, is this im­plau­si­ble? To my eye, this is right there in the de­ci­sion prob­lem, not a weird coun­ter­in­tu­itive con­se­quence of FDT: the de­ci­sion prob­lem stipu­lates that al­gorithms which out­put ‘left’ will not end up in the situ­a­tion of tak­ing a bomb, with very, very high prob­a­bil­ity.

  Again, com­plain­ing that you now know with cer­tainty that you’re in the un­lucky po­si­tion of see­ing the bomb seems ir­rele­vant in the way that a gam­bler com­plain­ing that they now know how the dice fell seems ir­rele­vant—it’s still best to gam­ble ac­cord­ing to the odds, tak­ing the op­tion which gives the best chance of suc­cess.

  (But what I most want to con­vey here is that there is a co­her­ent sense in which FDT does the op­ti­mal thing, whether or not one agrees with it.)

  One way of think­ing about this is to say that the FDT no­tion of “de­ci­sion prob­lem” is differ­ent from the CDT or EDT no­tion, in that FDT con­sid­ers the prior to be of pri­mary im­por­tance, whereas CDT and EDT con­sider it to be of no im­por­tance. If you had in­stead speci­fied ‘bomb’ with just the cer­tain in­for­ma­tion that ‘left’ is (causally and ev­i­den­tially) very bad and ‘right’ is much less bad, then CDT and EDT would re­gard it as pre­cisely the same de­ci­sion prob­lem, whereas FDT would con­sider it to be a rad­i­cally differ­ent de­ci­sion prob­lem.

  Another way to think about this is to say that FDT “re­jects” de­ci­sion prob­lems which are im­prob­a­ble ac­cord­ing to their own speci­fi­ca­tion. In cases like Bomb where the situ­a­tion as de­scribed is by its own de­scrip­tion a one in a trillion trillion chance of oc­cur­ring, FDT gives the out­come only one-trillion-trillion-th con­sid­er­a­tion in the ex­pected util­ity calcu­la­tion, when de­cid­ing on a strat­egy.

  Also, I note that this anal­y­sis (on the part of FDT) does not hinge in this case on ex­otic coun­ter­fac­tu­als. If you set Bomb up in the Sav­age frame­work, you would be forced to ei­ther give only the cer­tain choice be­tween bomb and not-bomb (so you don’t rep­re­sent the in­ter­est­ing part of the prob­lem, in­volv­ing the pre­dic­tor) or to give the de­ci­sion in terms of the prior, in which case the Sav­age frame­work would en­dorse the FDT recom­men­da­tion.

  Another frame­work in which we could ar­rive at the same anal­y­sis would be that of sin­gle-player ex­ten­sive-form games, in which the FDT recom­men­da­tion cor­re­sponds to the sim­ple no­tion of op­ti­mal strat­egy, whereas the CDT recom­men­da­tion amounts to the stipu­la­tion of sub­game-op­ti­mal­ity.

• abramdemski 13 Sep 2019 22:07 UTC

  24 points

  AF

  in reply to: abramdemski's comment on: A Cri­tique of Func­tional De­ci­sion Theory

  Re­ply­ing to one of Will’s ed­its on ac­count of my com­ments to the ear­lier draft:

  Fi­nally, in a com­ment on a draft of this note, Abram Dem­ski said that: “The no­tion of ex­pected util­ity for which FDT is sup­posed to do well (at least, ac­cord­ing to me) is ex­pected util­ity with re­spect to the prior for the de­ci­sion prob­lem un­der con­sid­er­a­tion.” If that’s cor­rect, it’s strik­ing that this crite­rion isn’t men­tioned in the pa­per. But it also doesn’t seem com­pel­ling as a prin­ci­ple by which to eval­u­ate be­tween de­ci­sion the­o­ries, nor does it seem FDT even does well by it. To see both points: sup­pose I’m choos­ing be­tween an av­o­cado sand­wich and a hum­mus sand­wich, and my prior was that I pre­fer av­o­cado, but I’ve since tasted them both and got­ten ev­i­dence that I pre­fer hum­mus. The choice that does best in terms of ex­pected util­ity with re­spect to my prior for the de­ci­sion prob­lem un­der con­sid­er­a­tion is the av­o­cado sand­wich (and FDT, as I un­der­stood it in the pa­per, would agree). But, un­con­tro­ver­sially, I should choose the hum­mus sand­wich, be­cause I pre­fer hum­mus to av­o­cado.

  Yeah, the thing is, the FDT pa­per fo­cused on ex­am­ples where “ex­pected util­ity ac­cord­ing to the prior” be­comes an un­clear no­tion due to log­i­cal un­cer­tainty is­sues. It wouldn’t have made sense for the FDT pa­per to fo­cus on that, given the de­sire to put the most difficult is­sues into fo­cus. How­ever, FDT is sup­posed to ac­com­plish similar things to UDT, and UDT pro­vides the more con­crete illus­tra­tion.

  The policy that does best in ex­pected util­ity ac­cord­ing to the prior is the policy of tak­ing what­ever you like. In games of par­tial in­for­ma­tion, de­ci­sions are defined as func­tions of in­for­ma­tion states; and in the situ­a­tion as de­scribed, there are sep­a­rate in­for­ma­tion states for lik­ing hum­mus and lik­ing av­o­cado. Choos­ing the one you like achieves a higher ex­pected util­ity ac­cord­ing to the prior, in com­par­i­son to just choos­ing av­o­cado no mat­ter what. In this situ­a­tion, op­ti­miz­ing the de­ci­sion in this way is equiv­a­lent to up­dat­ing on the in­for­ma­tion; but, not always (as in trans­par­ent new­comb, Bomb, and other such prob­lems).

  To re-state that a differ­ent way: in a given in­for­ma­tion state, UDT is choos­ing what to do as a func­tion of the in­for­ma­tion available, and judg­ing the util­ity of that choice ac­cord­ing to the prior. So, in this sce­nario, we judge the ex­pected util­ity of se­lect­ing av­o­cado in re­sponse to lik­ing hum­mus. This is worse (ac­cord­ing to the prior!) than se­lect­ing hum­mus in re­sponse to lik­ing hum­mus.

• abramdemski 13 Sep 2019 21:38 UTC

  55 points

  AF

  on: A Cri­tique of Func­tional De­ci­sion Theory

  I saw an ear­lier draft of this, and hope to write an ex­ten­sive re­sponse at some point. For now, the short ver­sion:

  As I un­der­stand it, FDT was in­tended as an um­brella term for MIRI-style de­ci­sion the­o­ries, which illus­trated the crit­i­cal points with­out mak­ing too many com­mit­ments. So, the vague­ness of FDT was partly by de­sign.

  I think UDT is a more con­crete illus­tra­tion of the most im­por­tant points rele­vant to this dis­cus­sion.

  • The op­ti­mal­ity no­tion of UDT is clear. “UDT gets the most util­ity” means “UDT gets the high­est ex­pected value with re­spect to its own prior”. This seems quite well-defined, hope­fully ad­dress­ing your (VII).

    • There are prob­lems ap­ply­ing UDT to re­al­is­tic situ­a­tions, but UDT makes perfect sense and is op­ti­mal in a straight­for­ward sense for the case of sin­gle-player ex­ten­sive form games. That doesn’t ad­dress multi-player games or log­i­cal un­cer­tainty, but it is enough for much of Will’s dis­cus­sion.

    • FDT fo­cused on the weird log­i­cal cases, which is in fact a ma­jor part of the mo­ti­va­tion for MIRI-style de­ci­sion the­ory. How­ever, UDT for sin­gle-player ex­ten­sive-form games ac­tu­ally gets at a lot of what MIRI-style de­ci­sion the­ory wants, with­out broach­ing the topic of log­i­cal coun­ter­fac­tu­als or prov­ing-your-own-ac­tion di­rectly.

    • The prob­lems which cre­ate a deep in­de­ter­mi­nacy seem, to me, to be prob­lems for other de­ci­sion the­o­ries than FDT as well. FDT is try­ing to face them head-on. But there are big prob­lems for ap­ply­ing EDT to agents who are phys­i­cally in­stan­ti­ated as com­puter pro­grams and can prove too much about their own ac­tions.

  • This also hope­fully clar­ifies the sense in which I don’t think the de­ci­sions pointed out in (III) are bizarre. The de­ci­sions are op­ti­mal ac­cord­ing to the very prob­a­bil­ity dis­tri­bu­tion used to define the de­ci­sion prob­lem.

    • There’s a sub­tle point here, though, since Will de­scribes the de­ci­sion prob­lem from an up­dated per­spec­tive—you already know the bomb is in front of you. So UDT “changes the prob­lem” by eval­u­at­ing “ac­cord­ing to the prior”. From my per­spec­tive, be­cause the very state­ment of the Bomb prob­lem sug­gests that there were also other pos­si­ble out­comes, we can rightly in­sist to eval­u­ate ex­pected util­ity in terms of those chances.

    • Per­haps this sounds like an un­prin­ci­pled re­jec­tion of the Bomb prob­lem as you state it. My prin­ci­ple is as fol­lows: you should not state a de­ci­sion prob­lem with­out hav­ing in mind a well-speci­fied way to pre­dictably put agents into that sce­nario. Let’s call the way-you-put-agents-into-the-sce­nario the “con­struc­tion”. We then eval­u­ate agents on how well they deal with the con­struc­tion.

      • For ex­am­ples like Bomb, the con­struc­tion gives us the over­all prob­a­bil­ity dis­tri­bu­tion—this is then used for the ex­pected value which UDT’s op­ti­mal­ity no­tion is stated in terms of.

      • For other ex­am­ples, as dis­cussed in De­ci­sions are for mak­ing bad out­comes in­con­sis­tent, the con­struc­tion sim­ply breaks when you try to put cer­tain de­ci­sion the­o­ries into it. This can also be a good thing; it means the de­ci­sion the­ory makes cer­tain sce­nar­ios al­to­gether im­pos­si­ble.

  The point about “con­struc­tions” is pos­si­bly a bit sub­tle (and hastily made); maybe a lot of the dis­agree­ment will turn out to be there. But I do hope that the ba­sic idea of UDT’s op­ti­mal­ity crite­rion is ac­tu­ally clear—“eval­u­ate ex­pected util­ity of poli­cies ac­cord­ing to the prior”—and clar­ifies the situ­a­tion with FDT as well.

Do Suffi­ciently Ad­vanced Agents Use Logic?

• abramdemski 13 Sep 2019 3:33 UTC

  2 points

  on: Ra­tion­al­ity Ex­er­cises Prize of Septem­ber 2019 ($1,000)

  By ask­ing peo­ple to leave a com­ment here link­ing to their ex­er­cises, are you dis­cour­ag­ing writ­ing ex­er­cises di­rectly as a com­ment to this post? (Per­haps you’re want­ing some­thing longer, and so dis­cour­ag­ing com­ments as the arena for list­ing ex­er­cises?)

• abramdemski 13 Sep 2019 3:01 UTC

  20 points

  AF

  in reply to: johnswentworth's comment on: Embed­ded Agency via Abstraction

  I agree that if a point can be ad­dressed or ex­plored in a static frame­work, it can be eas­ier to do that first rather than go­ing to the fully dy­namic pic­ture.

  On the other hand, I think your dis­cus­sion of the cat over­states the case. Your own anal­y­sis of the de­ci­sion the­ory of a sin­gle-cel­led or­ganism (ie the per­spec­tive you’ve de­scribed to me in per­son) com­pares it to gra­di­ent de­scent, rather than ex­pected util­ity max­i­miza­tion. This is a fuzzy area, and cer­tainly doesn’t achieve all the things I men­tioned, but doesn’t that seem more “dy­namic” than “static”? To­day’s deep learn­ing sys­tems aren’t as gen­er­ally in­tel­li­gent as cats, but it seems like the gap ex­ists more within learn­ing the­ory than static de­ci­sion the­ory.

  More im­por­tantly, al­though the static pic­ture can be eas­ier to analyse, it has also been much more dis­cussed for that rea­son. The low-hang­ing fruits are more likely to be in the more ne­glected di­rec­tion. Per­haps the more difficult parts of the dy­namic pic­ture (per­haps ro­bust del­e­ga­tion) can be put aside while still ap­proach­ing things from a learn­ing-the­o­retic per­spec­tive.

  I may have said some­thing along the lines of the static pic­ture already be­ing es­sen­tially solved by re­flec­tive or­a­cles (the prob­lems with re­flec­tive or­a­cles be­ing typ­i­cal of the prob­lems with the static ap­proach). From my per­spec­tive, it seems like time to move on to the dy­namic pic­ture in or­der to make progress. But that’s over­stat­ing things a bit—I am in­ter­ested in bet­ter static pic­tures, par­tic­u­larly when they are sug­ges­tive of dy­namic pic­tures, such as COEDT.

  In any case, I have no sense that you’re mak­ing a mis­take by look­ing at ab­strac­tion in the static set­ting. If you have trac­tion, you should con­tinue in that di­rec­tion. I gen­er­ally sus­pect that the ab­strac­tion an­gle is valuable, whether static or dy­namic.

  Still, I do sus­pect we have ma­te­rial dis­agree­ments re­main­ing, not only dis­agree­ments in re­search em­pha­sis.

  Toward the end of your com­ment, you speak of the one-shot pic­ture and the dy­namic pic­ture as if the two are mu­tu­ally ex­clu­sive, rather than just easy mode vs hard mode as you men­tion early on. A learn­ing pic­ture still ad­mits static snap­shots. Also, cats don’t get ev­ery­thing right on the first try.

  Still, I ad­mit: a weak­ness of an asymp­totic learn­ing pic­ture is that it seems to es­chew finite prob­lems; to such an ex­tent that at times I’ve said the dy­namic learn­ing pic­ture serves as the easy ver­sion of the prob­lem, with one-shot ra­tio­nal­ity be­ing the hard case to con­sider later. Toy static pic­tures—such as the one pro­vided by re­flec­tive or­a­cles—give an ideal­ized static ra­tio­nal­ity, us­ing un­bounded pro­cess­ing power and log­i­cal om­ni­science. A real static pic­ture—per­haps the pic­ture you are seek­ing—would in­volve bounded ra­tio­nal­ity, in­clud­ing both log­i­cal non-om­ni­science and reg­u­lar phys­i­cal non-om­ni­science. A static-ra­tio­nal­ity anal­y­sis of log­i­cal non-omn­in­cience has seemed quite challeng­ing so far. Nice ver­sions of self-refer­ence and other challenges to em­bed­ded world-mod­els such as those you men­tion seem to re­quire con­ve­niences such as re­flec­tive or­a­cles. Noth­ing re­sem­bling thin pri­ors has come along to al­low for even­tual log­i­cal co­her­ence while re­sem­bling bayesian static ra­tio­nal­ity (rather than log­i­cal-in­duc­tion-like dy­namic ra­tio­nal­ity). And as for the em­piri­cal un­cer­tainty, we would re­ally like to get some guaran­tees about avoid­ing catas­trophic mis­takes (though, per­haps, this isn’t within your scope).

• abramdemski 13 Sep 2019 1:30 UTC

  4 points

  AF

  in reply to: Vanessa Kosoy's comment on: For­mal­is­ing de­ci­sion the­ory is hard

  This might seem sur­pris­ing at first, be­cause there is also a differ­ent in­com­plete model Φ${}_2$ that says “if you pays the black­mail, in­fes­ta­tion will not hap­pen”. Φ${}_2$ is false if you use phys­i­cal causal coun­ter­fac­tu­als, but from the agent’s per­spec­tive Φ${}_2$ is con­sis­tent with all ob­ser­va­tions. How­ever, Φ${}_2$ only guaran­tees the pay­off −c (be­cause it is un­known whether the black­mail will ar­rive). There­fore, Φ${}_2$ will have no effect on the ul­ti­mate be­hav­ior of the agent.

  What hap­pens in ASP? (Say you’re in an iter­ated New­comb’s prob­lem with a pre­dic­tor much slower than you, but which meets the LIC or similar.) I’m con­cerned that it will ei­ther set­tle on two-box­ing, or pos­si­bly not set­tle on one strat­egy, since if it set­tles on two-box­ing then a model which says “you can get the higher re­ward by one-box­ing” (ie, the agent has con­trol over the pre­dic­tor) looks ap­peal­ing; but, if it set­tles on one-box­ing, a model which says “you can get higher re­ward by two-box­ing” (ie, the agent’s ac­tion doesn’t con­trol the pre­dic­tor) looks ap­peal­ing. This con­cern is re­lated to the way asymp­totic de­ci­sion the­ory fails—granted, for cases out­side of its defi­ni­tion of “fair”.

  The pre­com­mit­ments have to ex­pire af­ter some finite time.

  I agree that some­thing like this gen­er­ally does the right thing in most cases, with the ex­cep­tion of su­per­ra­tional­ity in games as a re­sult of com­mit­ment races.

  I still have a lit­tle hope that there will be a nice ver­sion, which doesn’t in­volve a com­mit­ment-races prob­lem and which doesn’t make use of an ar­bi­trary com­mit­ment cut­off. But I would agree that things don’t look good, and so it is rea­son­able to put this kind of thing out­side of “fair” prob­lems.

  Let me add that I am not even sure what are the cor­rect desider­ata. In par­tic­u­lar, I don’t think that we should ex­pect any group of good agents to con­verge to a Pareto op­ti­mal out­come.

  I don’t cur­rently see why we shouldn’t ask to con­verge to pareto op­tima. Ob­vi­ously, we can’t ex­pect to do so with ar­bi­trary other agents; but it doesn’t seem un­rea­son­able to use an al­gorithm which has the prop­erty of reach­ing pareto-op­tima with other agents who use that same al­gorithm. This even seems rea­son­able in the stan­dard iter­ated Nash pic­ture (where not all strate­gies achieve pareto op­tima, but there ex­ist strate­gies which achieve pareto op­tima with a broad-ish class of other strate­gies, in­clud­ing oth­ers who use strate­gies like their own—while be­ing very difficult to ex­ploit).

  But yeah, I’m pretty un­cer­tain about what the desider­ata should be—both with re­spect to game the­ory, and with re­spect to sce­nar­ios which re­quire up­date­less­ness/​pre­com­mit­ments in or­der to do well. I agree that it should all be ap­proached with a learn­ing-the­o­retic per­spec­tive.

• abramdemski 12 Sep 2019 20:00 UTC

  2 points

  AF

  in reply to: Ben Pace's comment on: For­mal­is­ing de­ci­sion the­ory is hard

  Ahh thanks :p fixed

• abramdemski 7 Sep 2019 5:17 UTC

  14 points

  AF

  on: Coun­ter­fac­tu­als are an An­swer, Not a Question

  Those of a Bayesian lean­ing will tend to say things like “prob­a­bil­ity is sub­jec­tive”, and claim this is an im­por­tant in­sight into the na­ture of prob­a­bil­ity—one might even go so far as to say “prob­a­bil­ity is an an­swer, not a ques­tion”. But this doesn’t mean you can be­lieve what you want; not ex­actly. There are co­her­ence con­straints. So, once we see that prob­a­bil­ity is sub­jec­tive, we can then seek a the­ory of the sub­jec­tivity, which tells us “ob­jec­tive” in­for­ma­tion about it (yet which leaves a whole lot of flex­i­bil­ity).

  The same might be true of coun­ter­fac­tu­als. I per­son­ally lean to­ward the po­si­tion that the con­straints on coun­ter­fac­tu­als are that they be con­sis­tent with ev­i­den­tial pre­dic­tions, but I don’t claim to be un­con­fused. My po­si­tion is a “coun­ter­fac­tu­als are sub­jec­tive but have sig­nifi­cant co­her­ence con­straints” type po­si­tion, but (ar­guably) a fairly min­i­mal one—the con­straint is a ver­sion of “coun­ter­fact­ing on what you ac­tu­ally did should yield what ac­tu­ally hap­pened”, one of the most ba­sic con­straints on what coun­ter­fac­tu­als should be.

  On the other hand, my the­ory of coun­ter­fac­tu­als is pretty bor­ing and doesn’t di­rectly solve prob­lems—it more says “look el­se­where for the in­ter­est­ing stuff”.

  Edit --

  Oh, also, I wanted to pitch the idea that coun­ter­fac­tu­als, like a whole bunch of things, should be thought of as “con­structed rather than real”. This is sub­tly differ­ent from “sub­jec­tive”. We hu­mans are pretty far along in an on­go­ing pro­cess of figur­ing out how to be and act in the world. Some­times we come up with for­mal the­o­ries of things like prob­a­bil­ity, util­ity, coun­ter­fac­tu­als, and logic. The pro­cess of com­ing up with these for­mal the­o­ries in­forms our prac­tice. Our prac­tice also in­forms the for­mal the­o­ries. Some­times a the­ory seems to cap­ture what we wanted re­ally nicely. My ar­gu­ment is that in an im­por­tant sense we’ve in­vented, not dis­cov­ered, what we wanted.

  So, for ex­am­ple, util­ity func­tions. Do util­ity func­tions cap­ture hu­man prefer­ences? No, not re­ally, they are pretty far from prefer­ences ob­served in the wild. How­ever, we’re in the pro­cess of figur­ing out what we pre­fer. Utility func­tions cap­ture some nice ideas about ideal­ized prefer­ences, so that when we’re talk­ing about ideal­ized ver­sions of what we want (try­ing to figure out what we pre­fer upon re­flec­tion) it is (a) of­ten pretty con­ve­nient to think in terms of util­ities, and (b) some­what difficult to re­ally es­cape the frame­work of util­ities. Similarly for prob­a­bil­ity and logic as for­mal mod­els of ideal­ized rea­son­ing.

  So, just as util­ity func­tions aren’t re­ally out there in the world, coun­ter­fac­tu­als aren’t re­ally out there in the world. But just as it might be that we should think about our prefer­ences in terms of util­ity any­way (...or maybe aban­don util­ity in fa­vor of bet­ter the­o­ret­i­cal tools), we might want to equip our best world-model with coun­ter­fac­tu­als any­way (...or aban­don them in fa­vor of bet­ter the­o­ret­i­cal tools).

• abramdemski 5 Sep 2019 21:56 UTC

  13 points

  AF

  in reply to: Vanessa Kosoy's comment on: For­mal­is­ing de­ci­sion the­ory is hard

  I very much agree with the point about not de­cou­pling learn­ing and de­ci­sion the­ory. I wrote a com­ment mak­ing some­what similar points.

  I be­lieve that this in­deed solves both INP and IXB.

  I’d like to un­der­stand this part.

  One way to fix it is by al­low­ing the agent to pre­com­mit. Then the as­sump­tion about Omega be­comes em­piri­cally ver­ifi­able.

  I’m not sure I should find the pre­com­mit­ment solu­tion satis­fy­ing. Won’t it make some stupid pre­com­mit­ments early (be­fore it has learned enough about the world to make rea­son­able pre­com­mit­ments) and screw it­self up for­ever? Is there a gen­er­ally ap­pli­ca­ble ver­sion of pre­com­mit­ments which en­sures learn­ing good be­hav­ior?

  The only class of prob­lems that I’m gen­uinely un­sure how to deal with is game-the­o­retic su­per­ra­tional­ity.

  If we take the learn­ing-the­o­retic view, then we get to bring in tools from iter­ated games. There’s a Pavlov-like strat­egy for play­ing de­ter­minis­tic iter­ated games which con­verges to op­ti­mal re­sponses to non-agen­tic en­vi­ron­ments and con­verges to Pareto op­tima for en­vi­ron­ments con­tain­ing agents who use the Pavlov-like strat­egy. It is not the great­est at be­ing un­ex­ploitable, and it also has fairly bad con­ver­gence.

  How­ever, I don’t yet see how to trans­late the re­sult to log­i­cal-in­duc­tion type learn­ers. Be­sides re­quiring de­ter­minis­tic pay­outs (a prop­erty which can prob­a­bly be re­laxed some­how), the al­gorithm re­quires an agent to have a definite his­tory—a well-defined train­ing se­quence. Agents based on log­i­cal in­duc­tion are in­stead form­ing gen­er­al­iza­tions based on any suffi­ciently analo­gous situ­a­tion within logic, so they don’t have a well-defined his­tory in the right way. (An ac­tual in­stance of a log­i­cal in­duc­tion agent has an ac­tual tem­po­ral his­tory, but this tem­po­ral his­tory is not nec­es­sar­ily what it is draw­ing on to play the game—it may have never per­son­ally en­coun­tered a similar situ­a­tion.)

  In other words, I’m hope­ful that there could be a learn­ing-the­o­retic solu­tion, but I don’t know what it is yet.

  As for su­per­ra­tional­ity for agents w/​o learn­ing the­ory, there’s co­op­er­a­tive or­a­cles, right? We can make com­putable analogues with dis­tributed or­a­cles. It’s not a real solu­tion, speci­fi­cally in that it ig­nores learn­ing. So I sort of think we know how to do it in the “static” set­ting, but the prob­lem is that we live in a learn­ing-the­o­retic set­ting rather than a static-ra­tio­nal­ity set­ting.

• abramdemski 4 Sep 2019 5:52 UTC

  25 points

  AF

  in reply to: johnswentworth's comment on: Embed­ded Agency via Abstraction

  The dice ex­am­ple is one I stum­bled on while play­ing with the idea of a prob­a­bil­ity-like calcu­lus for ex­clud­ing in­for­ma­tion, rather than in­clud­ing in­for­ma­tion. I’ll write up a post on it at some point.

  I look for­ward to it.

  When I imag­ine an em­bed­ded agent, I imag­ine some gi­ant com­pu­ta­tional cir­cuit rep­re­sent­ing the uni­verse, and I draw a box around one finite piece of it

  Speak­ing very ab­stractly, I think this gets at my ac­tual claim. Con­tin­u­ing to speak at that high level of ab­strac­tion, I am claiming that you should imag­ine an agent more as a flow through a fluid.

  Speak­ing much more con­cretely, this differ­ence comes partly from the ques­tion of whether to con­sider ro­bust del­e­ga­tion as a cen­tral part to tackle now, or (as you sug­gested in the post) a part to tackle later. I agree with your de­scrip­tion of ro­bust del­e­ga­tion as “hard mode”, but nonethe­less con­sider it to be cen­tral.

  To name some con­sid­er­a­tions:

  • The “static” way of think­ing in­volves hand­ing de­ci­sion prob­lems to agents with­out ask­ing how the agent found it­self in that situ­a­tion. The how-did-we-get-here ques­tion is some­times im­por­tant. For ex­am­ple, my re­jec­tion of the stan­dard smok­ing le­sion prob­lem is a how-did-we-get-here type ob­jec­tion.

  • More­over, “static” de­ci­sion the­ory puts a box around “epistemics” with an out­put to de­ci­sion-mak­ing. This im­plic­itly sug­gests: “De­ci­sion the­ory is about op­ti­mal ac­tion un­der un­cer­tainty—the gen­er­a­tion of that un­cer­tainty is rel­e­gated to epistemics.” This ig­nores the role of learn­ing how to act. Learn­ing how to act can be crit­i­cal even for de­ci­sion the­ory in the ab­stract (and is ob­vi­ously im­por­tant to im­ple­men­ta­tion).

  • View­ing things from a learn­ing-the­o­retic per­spec­tive, it doesn’t gen­er­ally make sense to view a sin­gle thing (a sin­gle ob­ser­va­tion, a sin­gle ac­tion/​de­ci­sion, etc) in iso­la­tion. So, ac­count­ing for log­i­cal non-om­ni­science, we can’t ex­pect to make a sin­gle de­ci­sion “cor­rectly” for ba­si­cally any no­tion of “cor­rectly”. What we can ex­pect is to be “mov­ing in the right di­rec­tion”—not at a par­tic­u­lar time, but gen­er­ally over time (if noth­ing kills us).

    • So, de­scribing an em­bed­ded agent in some par­tic­u­lar situ­a­tion, the no­tion of “ra­tio­nal (bounded) agency” should not ex­pect any­thing op­ti­mal about its ac­tions in that cir­cum­stance—it can only talk about the way the agent up­dates.

    • Due to log­i­cal non-om­ni­science, this ap­plies to the ac­tion even if the agent is at the point where it knows what’s go­ing on epistem­i­cally—it might not have learned to ap­pro­pri­ately re­act to the given situ­a­tion yet. So even “re­act­ing op­ti­mally given your (epistemic) un­cer­tainty” isn’t re­al­is­tic as an ex­pec­ta­tion for bounded agents.

  • Ob­vi­ously I also think the “dy­namic” view is bet­ter in the purely epistemic case as well—log­i­cal in­duc­tion be­ing the poster boy, to­tally break­ing the static rules of prob­a­bil­ity the­ory at a fixed time but grad­u­ally im­prov­ing its be­liefs over time (in a way which ap­proaches the static prob­a­bil­is­tic laws but also cap­tures more).

    • Even for purely Bayesian learn­ing, though, the dy­namic view is a good one. Bayesian learn­ing is a way of set­ting up dy­nam­ics such that bet­ter hy­pothe­ses “rise to the top” over time. It is quite analo­gous to repli­ca­tor dy­nam­ics as a model of evolu­tion.

  • You can do “equil­ibrium anal­y­sis” of evolu­tion, too (ie, evolu­tion­ary sta­ble equil­ibria), but it misses how-did-we-get-here type ques­tions: larger and smaller at­trac­tor bas­ins. (Evolu­tion­ar­ily sta­ble equil­ibria are sort of a patch on Nash equil­ibria to ad­dress some of the how-did-we-get-here ques­tions, by rul­ing out points which are Nash equil­ibria but which would not be at­trac­tors at all.) It also misses out on or­bits and other fun­da­men­tally dy­namic be­hav­ior.

    • (The dy­namic phe­nom­ena such as or­bits be­come im­por­tant in the the­ory of cor­re­lated equil­ibria, if you get into the liter­a­ture on learn­ing cor­re­lated equil­ibria (MAL—multi-agent learn­ing) and think about where the cor­re­la­tions come from.)

  Of course we could have agents which per­sist over time, col­lect­ing in­for­ma­tion and mak­ing mul­ti­ple de­ci­sions, but if our the­ory of em­bed­ded agency as­sumes that, then it seems like it will miss a lot of agenty be­hav­ior.

  I agree that re­quiring dy­nam­ics would miss some ex­am­ples of ac­tual sin­gle-shot agents, do­ing some­thing in­tel­li­gently, once, in iso­la­tion. How­ever, it is a live ques­tion for me whether such agents can be any­thing else that Boltz­mann brains. In Does Agent-like Be­hav­ior im­ply Agent-like Ar­chi­tec­ture, Scott men­tioned that it seems quite un­likely that you could get a look-up table which be­haves like an agent with­out hav­ing an ac­tual agent some­where causally up­stream of it. Similarly, I’m sug­gest­ing that it seems un­likely you could get an agent-like ar­chi­tec­ture sit­ting in the uni­verse with­out some kind of learn­ing pro­cess causally up­stream.

  More­over, con­ti­nu­ity is cen­tral to the ma­jor prob­lems and par­tial solu­tions in em­bed­ded agency. X-risk is a ro­bust del­e­ga­tion failure more than a de­ci­sion-the­ory failure or an em­bed­ded world-model failure (though sub­sys­tem al­ign­ment has a similarly strong claim). UDT and TDT are in­ter­est­ing largely be­cause of the way they es­tab­lish dy­namic con­sis­tency of an agent across time, par­tially ad­dress­ing the tiling agent prob­lem. (For UDT, this is es­pe­cially cen­tral.) But, both of them ul­ti­mately fail very much be­cause of their “static” na­ture.

  [I ac­tu­ally got this static/​dy­namic pic­ture from kom­pon­isto btw (talk­ing in per­son, though the posts give a taste of it). At first it sounded like rather free-flow­ing ab­strac­tion, but it kept sur­pris­ing me by be­ing able to bear weight. Line-per-line, though, much more of the above is in­spired by dis­cus­sions with Steve Ray­hawk.]

  Edit: Vanessa made a re­lated point in a com­ment on an­other post.

• abramdemski 4 Sep 2019 4:23 UTC

  4 points

  AF

  in reply to: VojtaKovarik's comment on: De­con­fuse Your­self about Agency: Ar­chi­tec­ture-morphization

  I think of agent-like ar­chi­tec­tures as some­thing ob­jec­tive, or re­lated to the ter­ri­tory. In con­trast, agent-like be­hav­ior is some­thing sub­jec­tive, some­thing in the map. Im­por­tantly, agent-like be­hav­ior, or the lack of it, of some X is some­thing that ex­ists in the map of some en­tity Y (where of­ten Y≠X).

  The se­lec­tion/​con­trol dis­tinc­tion seems re­lated, but not quite similar to me. Am I miss­ing some­thing there?

  A(Θ)-mor­phism seems to me to in­volve both agent-like ar­chi­tec­ture and agent-like be­hav­ior, be­cause it just talks about pre­dic­tion gen­er­ally. Mostly I was ask­ing if you were try­ing to point it one way or the other (we could talk about pre­dic­tion-of-in­ter­nals ex­clu­sively, to point at struc­ture, or pre­dic­tion-of-ex­ter­nal ex­clu­sively, to talk about be­hav­ior—I was un­sure whether you were try­ing to do one of those things).

  Since you say that you are try­ing to for­mal­ize how we in­for­mally talk, rather than how we should, I guess you weren’t try­ing to make A(Θ)-mor­phism get at this dis­tinc­tion at all, and were sep­a­rately men­tion­ing the dis­tinc­tion as one which should be made.

• abramdemski 4 Sep 2019 4:15 UTC

  11 points

  AF

  in reply to: Gurkenglas's comment on: Troll Bridge

  I don’t see how this agent seems to con­trol his san­ity.

  The agent in Troll Bridge thinks that it can make it­self in­sane by cross­ing the bridge. (Maybe this doesn’t an­swer your ques­tion?)

  Troll Bridge is a rare case where agents that re­quire proof to take ac­tion can prove they would be in­sane to take some ac­tion be­fore they’ve thought through its con­se­quences. Can you show how they could un­wisely do this in chess, or some sort of Troll Chess?

  I make no claim that this sort of case is com­mon. Sce­nar­ios where it comes up and is rele­vant to X-risk might in­volve alien su­per­in­tel­li­gences trol­ling hu­man-made AGI. But it isn’t ex­actly high on my list of con­cerns. The ques­tion is more about whether par­tic­u­lar the­o­ries of coun­ter­fac­tual are right. Troll Bridge might be “too hard” in some sense—we may just have to give up on it. But, gen­er­ally, these weird philo­soph­i­cal coun­terex­am­ples are more about point­ing out prob­lems. Com­plex real-life situ­a­tions are difficult to deal with (in terms of rea­son­ing about what a par­tic­u­lar the­ory of coun­ter­fac­tu­als will ac­tu­ally do), so we check sim­ple ex­am­ples, even if they’re out­landish, to get a bet­ter idea of what the coun­ter­fac­tu­als are do­ing in gen­eral.

• abramdemski 4 Sep 2019 4:05 UTC

  4 points

  AF

  in reply to: Chris_Leong's comment on: Troll Bridge

  Yep, sorry. The illus­tra­tions were not ac­tu­ally origi­nally meant for pub­li­ca­tion; they’re from my per­sonal notes. I did it this way (1) be­cause the pic­tures are kind of nice, (2) be­cause I was frus­trated that no one had writ­ten a good sum­mary post on Troll Bridge yet, (3) be­cause I was in a hurry. Ideally I’ll edit the images to be more suit­able for the post, al­though adding the omit­ted con­tent is a higher pri­or­ity.