summaryrefslogtreecommitdiff
path: root/doc/rfc/rfc1019.txt
diff options
context:
space:
mode:
Diffstat (limited to 'doc/rfc/rfc1019.txt')
-rw-r--r--doc/rfc/rfc1019.txt471
1 files changed, 471 insertions, 0 deletions
diff --git a/doc/rfc/rfc1019.txt b/doc/rfc/rfc1019.txt
new file mode 100644
index 0000000..8beb080
--- /dev/null
+++ b/doc/rfc/rfc1019.txt
@@ -0,0 +1,471 @@
+
+
+Network Working Group D. Arnon
+Request for Comments: 1019 Xerox PARC
+ September 1987
+
+
+
+ Report of the Workshop on Environments for Computational Mathematics
+ July 30, 1987
+ ACM SIGGRAPH Conference
+ Anaheim Convention Center, Anaheim, California
+
+
+Status of This Memo
+
+ This memo is a report on the discussion of the representation of
+ equations in a workshop at the ACM SIGGRAPH Conference held in
+ Anaheim, California on 30 July 1987. Distribution of this memo is
+ unlimited.
+
+Introduction
+
+ Since the 1950's, many researchers have worked to realize the vision
+ of natural and powerful computer systems for interactive mathematical
+ work. Nowadays this vision can be expressed as the goal of an
+ integrated system for symbolic, numerical, graphical, and
+ documentational mathematical work. Recently the development of
+ personal computers (with high resolution screens, window systems, and
+ mice), high-speed networks, electronic mail, and electronic
+ publishing, have created a technological base that is more than
+ adequate for the realization of such systems. However, the growth of
+ separate Mathematical Typesetting, Multimedia Electronic Mail,
+ Numerical Computation, and Computer Algebra communities, each with
+ its own conventions, threatens to prevent these systems from being
+ built.
+
+ To be specific, little thought has been given to unifying the
+ different expression representations currently used in the different
+ communities. This must take place if there is to be interchange of
+ mathematical expressions among Document, Display, and Computation
+ systems. Also, tools that are wanted in several communities (e.g.,
+ WYSIWYG mathematical expression editors), are being built
+ independently by each, with little awareness of the duplication of
+ effort that thereby occurs. Worst of all, the ample opportunities
+ for cross-fertilization among the different communities are not being
+ exploited. For example, some Computer Algebra systems explicitly
+ associate a type with a mathematical expression (e.g., 3 x 3 matrix
+ of polynomials with complex number coefficients), which could enable
+ automated math proofreaders, analogous to spelling checkers.
+
+ The goal of the Workshop on Environments for Computational
+ Mathematics was to open a dialogue among representatives of the
+
+
+
+Arnon [Page 1]
+
+RFC 1019 September 1987
+
+
+ Computer Algebra, Numerical Computation, Multimedia Electronic Mail,
+ and Mathematical Typesetting communities. In July 1986, during the
+ Computers and Mathematics Conference at Stanford University, a subset
+ of this year's participants met at Xerox PARC to discuss User
+ Interfaces for Computer Algebra Systems. This group agreed to hold
+ future meetings, of which the present Workshop is the first. Alan
+ Katz's recent essay, "Issues in Defining an Equations Representation
+ Standard", RFC-1003, DDN Network Information Center, March 1987
+ (reprinted in the ACM SIGSAM Bulletin May 1987, pp. 19-24),
+ influenced the discussion at the Workshop, especially since it
+ discusses the interchange of mathematical expressions.
+
+ This report does not aim to be a transcript of the Workshop, but
+ rather tries to extract the major points upon which (in the Editor's
+ view) rough consensus was reached. It is the Editor's view that the
+ Workshop discussion can be summarized in the form of a basic
+ architecture for "Standard Mathematical Systems", presented in
+ Section II below. Meeting participants seemed to agree that: (1)
+ existing mathematical systems should be augmented or modified to
+ conform to this architecture, and (2) future systems should be built
+ in accordance with it.
+
+ The Talks and Panel-Audience discussions at the Workshop were
+ videotaped. Currently, these tapes are being edited for submission
+ to the SIGGRAPH Video Review, to form a "Video Proceedings". If
+ accepted by SIGGRAPH, the Video Proceedings will be publicly
+ available for a nominal distribution charge.
+
+ One aspect of the mathematical systems vision that we explicitly left
+ out of this Workshop is the question of "intelligence" in
+ mathematical systems. This has been a powerful motivation to systems
+ builders since the early days. Despite its importance, we do not
+ expect intelligent behavior in mathematical systems to be realized in
+ the short term, and so we leave it aside. Computer Assisted
+ Instruction for mathematics also lies beyond the scope of the
+ Workshop. And although it might have been appropriate to invite
+ representatives of the Spreadsheets and Graphics communities, we did
+ not. Many of those who were at the Workshop have given considerable
+ thought to Spreadsheets and Graphics in mathematical systems.
+
+ Financial support from the Xerox Corporation for AudioVisual
+ equipment rental at SIGGRAPH is gratefully acknowledged. Thanks are
+ due to Kevin McIsaac for serving as chief cameraman, providing
+ critical comments on this report, and contributing in diverse other
+ ways to the Workshop. Thanks also to Richard Fateman, Michael
+ Spivak, and Neil Soiffer for critical comments on this report.
+ Subhana Menis and Erin Foley have helped with logistics and
+ documentation at several points along the way.
+
+ Information on the Video Proceedings, and any other aspect of the
+ Workshop can be obtained from the author of this report.
+
+
+
+Arnon [Page 2]
+
+RFC 1019 September 1987
+
+
+I. Particulars of the meeting
+
+ The Workshop had four parts: (1) Talks, (2) Panel Discussion, (3)
+ Panel and Audience discussion, (4) and Live demos. Only a few of the
+ systems presented in the talks were demonstrated live. However, many
+ of the talks contained videotapes of the systems being discussed.
+
+ The talks, each 15 minutes in length, were:
+
+ 1. "The MathCad System: a Graphical Interface for Computer
+ Mathematics", Richard Smaby, MathSOFT Inc.
+
+ 2. "MATLAB - an Interactive Matrix Laboratory", Cleve Moler,
+ MathWorks Inc.
+
+ 3. "Milo: A Macintosh System for Students", Ron Avitzur, Free Lance
+ Developer, Palo Alto, CA.
+
+ 4. "MathScribe: A User Interface for Computer Algebra systems", Neil
+ Soiffer, Tektronix Labs.
+
+ 5. "INFOR: an Interactive WYSIWYG System for Technical Text",
+ William Schelter, University of Texas.
+
+ 6. "Iris User Interface for Computer Algebra Systems", Benton Leong,
+ University of Waterloo.
+
+ 7. "CaminoReal: A Direct Manipulation Style User Interface for
+ Mathematical Software", Dennis Arnon, Xerox PARC.
+
+ 8. "Domain-Driven Expression Display in Scratchpad II", Stephen
+ Watt, IBM Yorktown Heights.
+
+ 9. "Internal and External Representations of Valid Mathematical
+ Reasoning", Tryg Ager, Stanford University.
+
+ 10. "Presentation and Interchange of Mathematical Expressions in the
+ Andrew System", Maria Wadlow, Carnegie-Mellon University.
+
+ The Panel discussion lasted 45 minutes. The panelists were:
+
+ Richard Fateman, University of California at Berkeley
+ Richard Jenks, IBM Yorktown Heights
+ Michael Spivak, Personal TeX
+ Ronald Whitney, American Mathematical Society
+
+
+
+
+
+
+
+
+
+Arnon [Page 3]
+
+RFC 1019 September 1987
+
+
+ The panelists were asked to consider the following issues in planning
+ their presentations:
+
+ 1. Should we try to build integrated documentation/computation
+ systems?
+
+ 2. WYSIWYG editing of mathematical expressions.
+
+ 3. Interchange representation of mathematics.
+
+ 4. User interface design for integrated documentation/computation
+ systems.
+
+ 5. Coping with large mathematical expressions.
+
+ A Panel-Audience discussion lasted another 45 minutes, and the Demos
+ lasted about one hour.
+
+ Other Workshop participants, besides those named above, included:
+
+ S. Kamal Abdali, Tektronix Labs
+ George Allen, Design Science
+ Alan Katz, Information Sciences Institute
+ J. Robert Cooke, Cornell University and Cooke Publications
+ Larry Lesser, Inference Corporation
+ Tom Libert, University of Michigan
+ Kevin McIsaac, Xerox PARC and University of Western Australia
+ Elizabeth Ralston, Inference Corporation
+
+II. Standard Mathematical Systems - a Proposed Architecture
+
+ We postulate that there is an "Abstract Syntax" for any mathematical
+ expression. A piece of Abstract Syntax consists of an Operator and
+ an (ordered) list of Arguments, where each Argument is (recursively)
+ a piece of Abstract Syntax. Functional Notation, Lisp SExpressions,
+ Directed Acyclic Graphs, and N-ary Trees are equivalent
+ representations of Abstract Syntax, in the sense of being equally
+ expressive, although one or another might be considered preferable
+ from the standpoint of computation and algorithms. For example, the
+ functional expression "Plus[Times[a,b],c]" represents the Abstract
+ Syntax of an expression that would commonly be written "a*b+c".
+
+ A "Standard Mathematical Component" (abbreviated SMC) is a collection
+ of software and hardware modules, with a single function, which if it
+ reads mathematical expressions, reads them as Abstract Syntax, and if
+ it writes mathematical expressions, writes them as Abstract Syntax.
+ A "Standard Mathematical System" (abbreviated SMS) is a collection of
+ SMC's which are used together, and which communicate with each other
+ in Abstract Syntax.
+
+ We identify at least four possible types of components in an SMS.
+
+
+
+Arnon [Page 4]
+
+RFC 1019 September 1987
+
+
+ Any particular SMS may have zero, one, or several instances of each
+ component type. The connection between two particular components of
+ an SMS, of whatever type, is via Abstract Syntax passed over a "wire"
+ joining them.
+
+ 1) EDs - Math Editors
+
+ These edit Abstract Syntax to Abstract Syntax. A particular system
+ may have editors that work on some other representations of
+ mathematics (e.g., bitmaps, or particular formatting languages),
+ however they do not qualify as an ED components of a SMS. An ED may
+ be WYSIWYG or language-oriented.
+
+ 2) DISPs - Math Displayers
+
+ These are suites of software packages, device drivers, and hardware
+ devices that take in an expr in Abstract Syntax and render it. For
+ example, (1) the combination of an Abstract Syntax->TeX translator,
+ TeX itself, and a printer, or (2) a plotting package plus a plotting
+ device. A DISP component may or may not support "pointing" (i.e.,
+ selection), within an expression it has displayed, fix a printer
+ probably doesn't, but terminal screen may. If pointing is supported,
+ then a DISP component must be able to pass back the selected
+ subexpression(s) in Abstract Syntax. We are not attempting here to
+ foresee, or limit, the selection mechanisms that different DISPs may
+ offer, but only to require that a DISP be able to communicate its
+ selections in Abstract Syntax.
+
+ 3) COMPs - Computation systems
+
+ Examples are Numerical Libraries and Computer Algebra systems. There
+ are questions as to the state of a COMP component at the time it
+ receives an expression. For example, what global flags are set, or
+ what previous expressions have been computed that the current
+ expression may refer to. However, we don't delve into these hard
+ issues at this time.
+
+ 4) DOCs - Document systems
+
+ These are what would typically called "text editors", "document
+ editors", or "electronic mail systems". We are interested in their
+ handling of math expressions. In reality, they manage other document
+ constituents as well (e.g., text and graphics). The design of the
+ user interface for the interaction of math, text, and graphics is a
+ nontrivial problem, and will doubtless be the subject of further
+ research.
+
+ A typical SMS will have an ED and a DISP that are much more closely
+ coupled than is suggested here. For example, the ED's internal
+ representation of Abstract Syntax, and the DISP's internal
+ representation (e.g., a tree of boxes), may have pointers back and
+
+
+
+Arnon [Page 5]
+
+RFC 1019 September 1987
+
+
+ forth, or perhaps may even share a common data structure. This is
+ acceptable, but it should always be possible to access the two
+ components in the canonical, decoupled way. For example, the ED
+ should be able to receive a standard Abstract Syntax representation
+ for an expression, plus an editing command in Abstract Syntax (e.g.,
+ Edit[expr, cmd]), and return an Abstract Syntax representation for
+ the result. Similarly, the DISP should be able to receive Abstract
+ Syntax over the wire and display it, and if it supports pointing, be
+ able to return selected subexpressions in Abstract Syntax.
+
+ The boundaries between the component types are not hard and fast. For
+ example, an ED might support simple computations (e.g.,
+ simplification, rearrangement of subexpressions, arithmetic), or a
+ DOC might contain a facility for displaying mathematical expressions.
+ The key thing for a given module to qualify as an SMC is its ability
+ to read and write Abstract Syntax.
+
+III. Recommendations and Qualifications
+
+ 1. It is our hypothesis that it will be feasible to encode a rich
+ variety of other languages in Abstract Syntax, for example,
+ programming constructs. Thus we intend it to be possible to
+ pass such things as Lisp formatting programs, plot programs,
+ TeX macros, etc. over the wire in Abstract Syntax. We also
+ hypothesize that it will be possible to encode all present and
+ future mathematical notations in Abstract Syntax (e.g.,
+ commutative diagrams in two or three dimensions). For
+ example, the 3 x 3 identify matrix might be encoded as:
+
+ Matrix[ [1,0,0], [0,1,0], [0,0,1] ]
+
+ while the Abstract Syntax expression:
+
+ Matrix[5, 5, DiagonalRow[1, ThreeDots[], 1],
+ BelowDiagonalTriangle[FlexZero[]],
+ AboveDiagonalTriangle[FlexZero[]]]
+
+ might encode a 5 x 5 matrix which is to be displayed with a
+ "1" in the (1,1) position, a "1" in the (5,5) position, three
+ dots between them on the diagonal, a big fat zero in the lower
+ triangle indicating the presence of zeros there, and a big fat
+ zero in the upper triangle indicating zeros.
+
+ 2. We assume the use of the ASCII character set for Abstract Syntax
+ expressions. Greek letters, for example, would need to be
+ encoded with expressions like Greek[alpha], or Alpha[].
+ Similarly, font encoding is achieved by the use of Abstract
+ Syntax such as the following for 12pt bold Times Roman:
+ Font[timesRoman, 12, bold, <expression>] Two SMCs are free to
+ communicate in a larger character set, or pass font
+ specifications in other ways, but they should always be able to
+
+
+
+Arnon [Page 6]
+
+RFC 1019 September 1987
+
+
+ express themselves in standard Abstract Syntax.
+
+ 3. COMPs (e.g., Computer Algebra systems), should be able to
+ communicate in Abstract Syntax. Existing systems should
+ have translators to/from Abstract Syntax added to them. In
+ addition, if we can establish a collection of standard names and
+ argument lists for common functions, and get all COMP's to read
+ and write them, then any Computer Algebra system will be able to
+ talk to any other. Some examples of possible standard names and
+ argument lists for common functions:
+
+ Plus[a,b,...]
+ Minus[a]
+ Minus[a,b]
+ Times[a,b,...]
+ Divide[<numerator>, <denominator>]
+ Power[<base>, <exponent>]
+ PartialDerivative[<expr>, <var>]
+ Integral[<expr>, <var>, <lowerLimit>,<upperLimit>] (limits optional)
+ Summation[<<summand>, <lowerLimit>, <upperLimit>] (limits optional)
+
+ A particular algebra system may read and write nonstandard
+ Abstract Syntax. For example:
+
+ Polynomial[Variables[x, y, z], List[Term[coeff, xExp, yExp, zExp],
+ ...
+
+ but, it should be able to translate this to an equivalent standard
+ representation. For example:
+
+ Plus[Times[coeff, Power[x, xExp], ...
+
+ 4. A DOC must store the Abstract Syntax representations of the
+ expressions it contains. Thus it's easy for it to pass its
+ expressions to EDs, COMPs, or DISPs. A DOC is free to store
+ additional expression representations. For example, a tree of
+ Boxes, a bitmap, or a TeX description.
+
+ 5. DISPs will typically have local databases of formatting
+ information. To actually render the Abstract Syntax, the DISP
+ checks for display rules in its database. If none are found,
+ it paints the Abstract Syntax in some standard way. Local
+ formatting databases can be overridden by formatting rules passed
+ over the wire, expressed in Abstract Syntax. It is formatting
+ databases that store knowledge of particular display
+ environments (for e.g., "typesetting for Journal X").
+
+ The paradigm we wish to follow is that of the genetic code: A
+ mathematical expression is like a particular instance of DNA, and
+ upon receiving it a DISP consults the appropriate formatting
+ database to see if it understands it. If not, the DISP just
+
+
+
+Arnon [Page 7]
+
+RFC 1019 September 1987
+
+
+ "passed it through unchanged". The expression sent over the wire
+ may be accompanied by directives or explanatory information,
+ which again may or may not be meaningful to a particular DISP. In
+ reality, formatting databases may need to contain Expert
+ System-level sophistication to be able to produce professional
+ quality typesetting results, but we believe that useful results
+ can be achieved even without such sophistication.
+
+ 6. With the use of the SMC's specified above, it becomes easy to use
+ any DOC as a logging facility for a session with a COMP. Therefore,
+ improvements in DOCs (e.g., browsers, level structuring, active
+ documents, audit trails), will automatically give us better
+ logging mechanisms for sessions with algebra systems.
+
+ 7. Note that Abstract Syntax is human-readable. Thus any text
+ editor can be used as an ED. Of course, in a typical SMS, users
+ should have no need to look at the Abstract Syntax flowing
+ through the internal "wires" if they don't care to. Many will
+ want to interact only with mathematics that has a textbook-like
+ appearance, and they should be able to do so.
+
+ 8. Alan Katz's RFC (cited above) distinguishes the form (i.e.,
+ appearance) of a mathematical expression from its content (i.e.,
+ meaning, value). We do not agree that such a distinction can be
+ made. We claim that Abstract Syntax can convey form, meaning,
+ or both, and that its interpretation is strictly in the eye
+ of the beholder(s). Meaning is just a handshake between sender
+ and recipient.
+
+ 9. Help and status queries, the replies to help and status queries,
+ and error messages should be read and written by SMC's in
+ Abstract Syntax.
+
+ 10. In general, it is permissible for two SMC's to use private
+ protocols for communication. Our example of a tightly coupled ED
+ and DISP above is one example. Two instances of a Macsyma COMP
+ would be another; they might agree to pass Macsyma internal
+ representations back and forth. To qualify as SMC's, however,
+ they should be able to translate all such exchanges into
+ equivalent exchanges in Abstract Syntax.
+
+
+
+
+
+
+
+
+
+
+
+
+
+
+Arnon [Page 8]
+