The two major paradigms for constructing semantic software systems were procedural and logical. The procedural paradigm was epitomized by
Lisp[2] which featured recursive procedures that operated on list structures.
The logical paradigm was epitomized by uniform proof procedure resolution-based derivation (proof) finders.[3] According to the logical paradigm it was “cheating” to incorporate procedural knowledge.[4]
Planner was invented for the purposes of the procedural embedding of knowledge[5] and was a rejection of the resolution uniform proof procedure paradigm,[6] which
Converted everything to clausal form. Converting all information to clausal form is problematic because it hides the underlying structure of the information.
Then used resolution to attempt to obtain a proof by contradiction by adding the clausal form of the negation of the theorem to be proved. Using only resolution as the rule of inference is problematical because it hides the underlying structure of proofs. Also, using proof by contradiction is problematical because the axiomatizations of all practical domains of knowledge are inconsistent in practice.
Planner was a kind of hybrid between the procedural and logical paradigms because it combined programmability with logical reasoning. Planner featured a procedural interpretation of logical sentences where an implication of the form (P implies Q) can be procedurally interpreted in the following ways using pattern-directed invocation:
A subset called Micro-Planner was implemented by Gerry Sussman, Eugene Charniak and Terry Winograd[7] and was used in Winograd's natural-language understanding program SHRDLU, Eugene Charniak's story understanding work, Thorne McCarty's work on legal reasoning, and some other projects. This generated a great deal of excitement in the field of AI. It also generated controversy because it proposed an alternative to the logic approach that had been one of the mainstay paradigms for AI.
AtSRI International, Jeff Rulifson, Jan Derksen, and Richard Waldinger developed QA4 which built on the constructs in Planner and introduced a context mechanism to provide modularity for expressions in the database. Earl Sacerdoti and Rene Reboh developed QLISP, an extension of QA4 embedded in INTERLISP, providing Planner-like reasoning embedded in a procedural language and developed in its rich programming environment. QLISP was used by Richard Waldinger and Karl Levitt for program verification, by Earl Sacerdoti for planning and execution monitoring, by Jean-Claude Latombe for computer-aided design, by Nachum Dershowitz for program synthesis, by Richard Fikes for deductive retrieval, and by Steven Coles for an early expert system that guided use of an econometric model.
Computers were expensive. They had only a single slow processor and their memories were very small by comparison with today. So Planner adopted some efficiency expedients including the following:
Backtracking[8] was adopted to economize on the use of time and storage by working on and storing only one possibility at a time in exploring alternatives.
A unique name assumption was adopted to save space and time by assuming that different names referred to different objects. For example, names like Peking (previous PRC capital name) and Beijing (current PRC capital transliteration) were assumed to refer to different objects.
Aclosed-world assumption could be implemented by conditionally testing whether an attempt to prove a goal exhaustively failed. Later this capability was given the misleading name "negation as failure" because for a goal G it was possible to say: "if attempting to achieve G exhaustively fails then assert (Not G)."
Gerry Sussman, Eugene Charniak, Seymour Papert and Terry Winograd visited the University of Edinburgh in 1971, spreading the news about Micro-Planner and SHRDLU and casting doubt on the resolution uniform proof procedure approach that had been the mainstay of the Edinburgh Logicists. At the University of Edinburgh, Bruce Anderson implemented a subset of Micro-Planner called PICO-PLANNER,[9] and Julian Davies (1973) implemented essentially all of Planner.
According to Donald MacKenzie, Pat Hayes recalled the impact of a visit from Papert to Edinburgh, which had become the "heart of artificial intelligence's Logicland," according to Papert's MIT colleague, Carl Hewitt. Papert eloquently voiced his critique of the resolution approach dominant at Edinburgh "…and at least one person upped sticks and left because of Papert."[10]
The above developments generated tension among the Logicists at Edinburgh. These tensions were exacerbated when the UK Science Research Council commissioned Sir James Lighthill to write a report on the AI research situation in the UK. The resulting report [Lighthill 1973; McCarthy 1973] was highly critical although SHRDLU was favorably mentioned.
Pat Hayes visited Stanford where he learned about Planner. When he returned to Edinburgh, he tried to influence his friend Bob Kowalski to take Planner into account in their joint work on automated theorem proving. "Resolution theorem-proving was demoted from a hot topic to a relic of the misguided past. Bob Kowalski doggedly stuck to his faith in the potential of resolution theorem proving. He carefully studied Planner.”.[11] Kowalski [1988] states "I can recall trying to convince Hewitt that Planner was similar to SL-resolution." But Planner was invented for the purposes of the procedural embedding of knowledge and was a rejection of the resolution uniform proof procedure paradigm. Colmerauer and Roussel recalled their reaction to learning about Planner in the following way:
"While attending an IJCAI convention in September ‘71 with Jean Trudel, we met Robert Kowalski again and heard a lecture by Terry Winograd on natural language processing. The fact that he did not use a unified formalism left us puzzled. It was at this time that we learned of the existence of Carl Hewitt’s programming language, Planner. The lack of formalization of this language, our ignorance of Lisp and, above all, the fact that we were absolutely devoted to logic meant that this work had little influence on our later research."[12]
In the fall of 1972, Philippe Roussel implemented a language called Prolog (an abbreviation for PROgrammation en LOGique – French for "programming in logic"). Prolog programs are generically of the following form (which is a special case of the backward-chaining in Planner):
When goal Q, goalP1and ... and goalPn
Prolog duplicated the following aspects of Micro-Planner:
Pattern directed invocation of procedures from goals (i.e.backward chaining)
An indexed data base of pattern-directed procedures and ground sentences.
Giving up on the completeness paradigm that had characterized previous work on theorem proving and replacing it with the programming language procedural embedding of knowledge paradigm.
Prolog also duplicated the following capabilities of Micro-Planner which were pragmatically useful for the computers of the era because they saved space and time:
Backtracking control structure
Unique Name Assumption by which different names are assumed to refer to distinct entities, e.g., Peking and Beijing are assumed to be different.
Reification of Failure. The way that Planner established that something was provable was to successfully attempt it as a goal and the way that it establish that something was unprovable was to attempt it as a goal and explicitly fail. Of course the other possibility is that the attempt to prove the goal runs forever and never returns any value. Planner also had a (not expression) construct which succeeded if expression failed, which gave rise to the “Negation as Failure” terminology in Planner.
Use of the Unique Name Assumption and Negation as Failure became more questionable when attention turned to Open Systems.[13]
The following capabilities of Micro-Planner were omitted from Prolog:
Pattern-directed invocation of procedural plans from assertions (i.e., forward chaining)
Logical negation, e.g., (not (human Socrates)).
Prolog did not include negation in part because it raises implementation issues. Consider for example if negation were included in the following Prolog program:
not Q.
Q :- P.
The above program would be unable to prove notP even though it follows by the rules of mathematical logic. This is an illustration of the fact that Prolog (like Planner) is intended to be a programming language and so does not (by itself) prove many of the logical consequences that follow from a declarative reading of its programs.
The work on Prolog was valuable in that it was much simpler than Planner. However, as the need arose for greater expressive power in the language, Prolog began to include many of the capabilities of Planner that were left out of the original version of Prolog.
Bruce Anderson. Documentation for LIB PICO-PLANNER School of Artificial Intelligence, Edinburgh University. 1972
Bruce Baumgart. Micro-Planner Alternate Reference Manual Stanford AI Lab Operating Note No. 67, April 1972.
Coles, Steven (1975), "The Application of Artificial Intelligence to Heuristic Modeling", 2nd US-Japan Computer Conference.
Fikes, Richard (1975), Deductive Retrieval Mechanisms for State Description Models, IJCAI.
Fitch, Frederic (1952), Symbolic Logic: an Introduction, New York: Ronald Press.
Green, Cordell (1969), "Application of Theorem Proving to Problem Solving", IJCAI.
Hewitt, Carl (1969). "PLANNER: A Language for Proving Theorems in Robots". IJCAI. CiteSeerX10.1.1.80.756.
Hewitt, Carl (1971), "Procedural Embedding of Knowledge In Planner", IJCAI.
Carl Hewitt. "The Challenge of Open Systems" Byte Magazine. April 1985
Carl Hewitt and Jeff Inman. 『DAI Betwixt and Between: From ‘Intelligent Agents’ to Open Systems Science』IEEE Transactions on Systems, Man, and Cybernetics. Nov/Dec 1991.
Carl Hewitt and Gul Agha. "Guarded Horn clause languages: are they deductive and Logical?" International Conference on Fifth Generation Computer Systems, Ohmsha 1988. Tokyo. Also in Artificial Intelligence at MIT, Vol. 2. MIT Press 1991.
McCarthy, John; Abrahams, Paul; Edwards, Daniel; Hart, Timothy; Levin, Michael (1962), Lisp 1.5 Programmer's Manual, MIT Computation Center and Research Laboratory of Electronics.
Robinson, John Alan (1965), "A Machine-Oriented Logic Based on the Resolution Principle", Communications of the ACM, 12: 23–41, doi:10.1145/321250.321253.
Julian Davies. Popler 1.6 Reference Manual University of Edinburgh, TPU Report No. 1, May 1973.
Jeff Rulifson, Jan Derksen, and Richard Waldinger. "QA4, A Procedural Calculus for Intuitive Reasoning" SRI AI Center Technical Note 73, November 1973.
Scott Fahlman. "A Planning System for Robot Construction Tasks" MIT AI TR-283. June 1973
James Lighthill. "Artificial Intelligence: A General Survey Artificial Intelligence: a paper symposium." UK Science Research Council. 1973.
John McCarthy.『Review of ‘Artificial Intelligence: A General Survey Artificial Intelligence: a paper symposium.』UK Science Research Council. 1973.
Pat Hayes. Computation and Deduction Mathematical Foundations of Computer Science: Proceedings of Symposium and Summer School, Štrbské Pleso, High Tatras, Czechoslovakia, September 3–8, 1973.
Carl Hewitt, Peter Bishop and Richard Steiger. "A Universal Modular Actor Formalism for Artificial Intelligence" IJCAI 1973.
L. Thorne McCarty. "Reflections on TAXMAN: An Experiment on Artificial Intelligence and Legal Reasoning" Harvard Law Review. Vol. 90, No. 5, March 1977
