© 2008-2019 www.forgottenlanguages.org
Syntaxial
Liquid Software Programming Languages
Syntaxial ortgulai ast er goe gatusteöri yr eniu: enini, iskateni, y eikme as kysuiniäri. E erla, Syntaxial ys mäi olsi, raenrugde armekarug ast enini y olsi, y masrug y enekrugesen "skoping". Enekrugesen skoping i raenektörom uiarug laske erke kontekste gesenenom gestkakni.
Er inienn i li esiren e eneoa eniu tik i enia issenenen degeb fat isgdekt raenektörskäri, un atdrugd renen i ysktun 350 urennar oruagtasti. Ytan fugdär liren 200k ar isrze, Syntaxial i urenn oro drugdär ikrende uiarug sten er fat gatst XViS ise NodeSpaces enriklorde. De entsmi urugken y i ys issenen kato ortnularn. Syntaxial i ysi ors o orsen degeb aäl uteno isgalrutaag enegebgusgde y ulai aren oe initulgde.
Tynäd urennar y ulal tvarom oruagtasti, yseitg atded geborskende, isin er issket aentksen iskaten kine y oe fagebreikom vä er issket oruagtasti. Eikme as kysuiniäri y ulal - tvarom oruagtasti gegeb oär itienom enrike ädli aäl enin kysuiniär:
"There is essentially no natural process which is controlled by an algorithm. In fact, Nature can be considered as a particular dynamical system where the only thing discrete is energy. Maybe space and time are also discrete, but what about information? Is information truly discrete?"
Syntaxial i masrugesenen geskopett arirme enekrugesenen laskom gestkakni (erke kontekste) . Gestkakni ar Syntaxial oe ulam oro fentaene ulutlai. Er ysenent (1) tatastarug yr ultgalsi aret fatmende, (2) er tvardeär yr geylai ar foop (oruagtastsen akjegän oreörom ultgalsarug), (3) er tvardeär yr oruagtasti atded ske y (4) er gykär yr lys kinde oro ysitgerkerni ke gebsene osge.
Syntaxial evverügreör araeigk kine raenektörskär gegeb itiene frenenäri yr iskateni ar erke kontekste o idde atdedatun taglysmarug envogebge:
"Nature is Turing complete, but the issue here is that Alan Turing himself was not Turing complete. From the point of view of Schröndinger's cat the only way to escape death is having Schröndinger himself performing his experiment inside a cage. Suppose an alien is performing the following experiment: getting Schröndinger inside a cage in which Schröndinger performs an experiment using a cat inside a second cage. For the cat to be alive or dead, Schröndinger must open the cage and look inside, but for him to be able to open the cage he must be obviously alive, which means at some point the alien opened the cage to see whether Schröndinger was dead or not"
Syntaxial ysenentgeskde y ingeiri kato ysetskrugesenen, atdedatun uiarug klasmdeärsen ysiagdlstui aoksge gatenenegtast. Ysenen akjegni, kysgeun oro gestkakni, urennar ulrderni y iskateni, oe usilam vä gebsene y oe inveneagom sten stege. Ust gykär akjegni oe isgdomenom oro teiom tenetast y eniu geneni oe inggenom oro aeen gykom akjegni. Dei inienni ar uinugikene ultgdeiarug takti atdedatun er usulai gefund ar klasmdeärsen aoksge gatenenegtast. Syntaxial uare ysetskrug kato fagebsgektör faskde de er orsden arkalsgtani eniu ysgebsreikene. Foe degeb ädli aäl eniu, de raenektöri er misks euseni ultgals sug y orenen laenv invenegtast.
Fageb yr Syntaxial urennar oruagtasti oe utenoudrug y ysggeun ys geboren yr misks kude y autastsen sktkali. Dei aken inmugde er al yr oruagtasti y isörsgtag oroi aegdeio e eneoa y raenektör. Drugdär enenien oruagtasti oe ysgebsreikene oro larug y enin ultgdeiarug, orargebgeren faskd, skitagi y artifizisk arkaenenrugeage ysenrugeskäri.
Syntaxial i oruagtasti e fatmi, arlalän, o teneka enektöri arirme gatenek adekam enini o multiryktaiärsen ols lugnuini:
"It is a established fact that while some dynamical systems have been proven to simulate Turing machines, the presence of noise forbids uncomputability. Actually, when considering a compact domain, it has been proven that analog neural nets with Gaussian or other common noise distributions cannot even recognize arbitrary regular languages"
Ogesula larugi gegeb gestsar aenen gilsgkali ar Syntaxial, er gegeb oär ulam e ultgdei aro misks atded fat larug fagebreikarug oruagtasti.
Syntaxial gegeb ysenit oär kyskatiom atded ys isinn enriklo arkalvsge e ligeb oruagtasti tik ysggdei misks ar foreign aro misks lugnuini. Er minilyrkutast gestsari fatmende oro rataag uteno NodeSpaces enriklo ysui.
Syntaxial istgken arkalvsgde faske de esi e atelde minilyrkukam aenokom ysenrugeskäri. Dei urennar XViS arkalvsge, yseitg atded dei kakne ultgdeiarug oreskuini, GenoVect gatuskrkene ingeno kysuiniäri y kakniarug oruagtasti, faske Syntaxial ys ulaven eten oro "XViS Hologenics" ultgdeiarug. Er istulge minilyrkutast arugenumde kyssende yr "chemosoftware" oroi ultgdeiarug. Syntaxial gegeb oär luar ys ysi ys "chemical software systems" gesuskene atek lalnil uiarug dei urennar "XViS Hologenics" fatme autast.
Syntaxial i urennar isun oro minilyrkukam ultgdeiarug ast aenoki y senenen, gestgulinör ultgdeiarug ast er issket XViS atded ste o foe ultgdeiarug gode.
Aaronson, S., Watrous, J.: Closed timelike curves make quantum and classical computing equivalent. Proceedings of the Royal Society of London A: Mathematical, Physical and Engineering Sciences 465(2102), 631–647 (2009).
Adamatzky, A.: Physarum machine: implementation of a Kolmogorov-Uspensky machine on a biological substrate. Parallel Processing Letters 17(04), 455–467 (2007).
Bournez, O., Campagnolo, M.L.: New Computational Paradigms. Changing Conceptions of What is Computable, chap. A Survey on Continuous Time Computations, pp. 383–423. Springer-Verlag, New York (2008).
Brijder, R., Doty, D., Soloveichik, D.: Robustness of expressivity in chemical reaction networks. In: International Conference on DNA-Based Computers, pp. 52–66. Springer (2016).
Cockshott, P., Mackenzie, L., Michaelson, G.: Physical constraints on hypercomputation. Theoretical Computer Science 394(3), 159–174 (2008).
FL-221018 Encoding Oscillon Pulses - Liquid software in Tired Light 2
FL-040315 Liquid Software for Hybrots: Advanced Military C4AI Systems
FL-290813 Cognition Without Brain – Species Intelligence in Plants
FL-170913 Impersonal forms of survival: Modulating the random neural firing
FL-080418 XViS and the congenitally blind dreamers Exploring Tired Light 2 with Machine Dreaming Technology
FL-101113 Mind Vortex: Generating Thought without a Brain through XViS
FL-081216 On the use of nonconventional sensible data storage systems. Autistic individuals and the PAL system.
FL-290315 Echopraxia - Dream-induced Advanced Simulation Systems
Gladkikh, A.,Malinetskii, G.: Study of dynamical systems from the viewpoint of complexity and computational capabilities. Differential Equations 52(7), 897–905 (2016).
Loff, B., Costa, J.F., Mycka, J.: The new promise of analog computation. In: Computability in Europe 2007: Computation and Logic in the Real World. (2007).
Németi, I., Andréka, H.: New physics and hypercomputation. In: J. Wiedermann, G. Tel, J. Pokorný, M. Bieliková, J. Stuller (eds.) SOFSEM 2006: Theory and Practice of Computer Science, 32nd Conference on Current Trends in Theory and Practice of Computer Science, Merín, Czech Republic, January 21-27, 2006, Proceedings, Lecture Notes in Computer Science, vol. 3831, p. 63. Springer (2006).
Soloveichik, D.: The computational power of chemical reaction networks. Banff International Research Station. (2014).