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Axiom is a free, open source computer algebra system
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"What matters the most is what you do for free" -- John Gorka "...even more important, for the progress of mathematics in the computer age, is the beaver, who will build the needed infrastructure of computer mathematics, that would eventually enable us to solve many outstanding open problems, and many new ones. Consequently, the developers of computer algebra systems, and creators of algorithms, are even more important than both birds and frogs." --Doron Zeilberger (http://www.math.rutgers.edu/~zeilberg/Opinion95.html) Listening to computer scientists argue, it seems that the standards of proof is I've had two beers and there is this anecdote about a tribe in New Guinea from one of Scott Birkins books that seems to be applicable. The debate is hindered by low standards of proof. -- Greg Wilson "What We Actually Know About Software Development" https://vimeo.com/9270320 Thinking, analyzing, and inventing are not anomalous acts; they are the normal respiration of the intelligence. -- Zero HP Lovecraft (The Gig Economy) https://zerohplovecraft.wordpress.com/2018/05/11/the-gig-economy-2 When you teach, you do something useful. When you do research, most days you don't. -- June Huh IAS Princeton Therapist: So you're afraid that you're letting down people you've never met and who you've given something for free? Me: Yeah, basically -- Matthew Garrett Only those who aren't trying to make money can afford to advance a technology that doesn't pay. -- Robert X. Cringely You've unpacked the Axiom source code to some directory. In this document we'll call that directory /home/me/axiom. Note that the path cannot contain spaces. ======================================================================= ================= MAKING AXIOM ======================================== ======================================================================= Axiom builds a system-specific version based on a string we'll call the SYSNAME. Currently recognized SYSNAME strings can be found on the Axiom website at: <http://axiom.axiom-developer.org/axiom-website/download.html> Replace SYSNAME below with the likely name of your system. We also assume that you downloaded AXIOM to someplace. Suppose that place is /home/me/axiom, then: cd /home/me/axiom << where you unpacked the sources export AXIOM=/home/me/axiom/mnt/SYSNAME << which axiom to build export PATH=$AXIOM/bin:$PATH make << build the system A recent cause of likely build failures is SELinux. See the faq file for possible solutions. When the make completes you'll have an executable called $AXIOM/bin/axiom ======================================================================= ================= INSTALLING AXIOM ==================================== ======================================================================= You can install Axiom on your system by typing (as root): make install This will put Axiom into /usr/local/axiom and the axiom command in /usr/local/bin/axiom You can change these defaults to anything thus: make INSTALL=/home/me/myaxiom COMMAND=/home/me/bin/myaxiom install ===================================================================== Documentation can be found at various places in the system or on the Axiom website: <http://axiom.axiom-developer.org> There is a book (available on Amazon.com): Jenks, Richard D. and Sutor, Robert S. "Axiom, The Scientific Computation System" Springer-Verlag, NY, 1992, ISBN 0-387-97855-0 The book is automatically built as part of the make and lives in: (yourpath)/axiom/mnt/(sysname)/doc/bookvol0.pdf In general every directory will contain a Makefile.dvi file. These files document facts about how Axiom is built. The directory mnt/linux/doc will contain .dvi files as they are written. Axiom is free and open source software. It is copyrighted code that is released under the Modified BSD license. Much debate about this topic has already been archived on the axiom-legal and axiom-developer mailing lists. The mail archives are available at the Axiom website: http://savannah.gnu.org/projects/axiom For the purposes of copyright, Axiom is to be considered "Joint Work". Specifically: "A joint work is a work prepared by two or more individuals, with the intention that their separate contributions be merged into a single work. A joint author can also be an organization or a corporation under the definition of "work for hire." A person who has merely contributed ideas without actually documenting those ideas generally cannot be considered an author. Authors own the work jointly and equally, unless the authors make an agreement otherwise. Each joint author has the right to exercise any or all of the exclusive rights inherent in the joint work. Each author may: * Grant thirds parties permission to use the work on a nonexclusive basis without the consent of the other joint authors * Transfer his or her entire ownership interest to another person without the other joint author's consent * Update the work for his or her own purpose Additionally, each joint author must account to the other joint authors for any profits received from licensing their joint work." (http://copyright.universityofcalifornia.edu/ownership/joint-works.html) Questions and comments should be sent to: [email protected] Tim Daly [email protected] ===================================================================== Philosophy Scratchpad was a large, general purpose computer algebra system that was originally developed by IBM under the direction of Richard Jenks. The project started in 1971 and evolved slowly. Barry Trager was key to the technical direction of the project. Scratchpad developed over a 20 year stretch and was basically considered as a research platform for developing new ideas in computational mathematics. In the 1990s, as IBM's fortunes slid, the Scratchpad project was renamed to Axiom, sold to the Numerical Algorithms Group (NAG) in England and became a commercial system. As part of the Scratchpad project at IBM in Yorktown I worked on all aspects of the system and eventually helped transfer the product to NAG. For a variety of reasons it never became a financial success and NAG withdrew it from the market in October, 2001. NAG agreed to release Axiom as free software. The basic motivation was that Axiom represents something different from other programs in a lot of ways. Primarily because of its foundation in mathematics the Axiom system will potentially be useful 30 years from now. In its current state it represents about 30 years and 300 man-years of research work. To strive to keep such a large collection of knowledge alive seems a worthwhile goal. However, keeping Axiom alive means more than just taking the source code and dumping it onto a public server. There are a lot of things about the system that need to change if it is going to survive and thrive for the next 30 years. The system is complex and difficult to build. There are few people who know how it is structured and why it is structured that way. Somehow it needs to be documented deeply so others can contribute. The mathematics is difficult. Unlike other free software you can't just reach for the old saying ``read the source code''. The source code is plain, clear and about as close to the mathematical theory as is practical. Unfortunately the mathematical theory is enshrined in some research library where few people will have access. Somehow this must change. The research work, the mathematics, the published papers, and the source code have all got to be kept together for the next generation to read, understand and modify. The mathematics is narrow and very focused. This was due to the fact that, while Axiom is a great research platform, we only had a limited number of visitors at IBM Research. So there is very little in the way of, say, infinite group theory in Axiom. We can add it. Doing so will show up shortcomings in the system. For example, how do you represent an infinite object? There are many possible representations and they depend on your goals. The system will have to change, expand, and, hopefully, become cleaner as more thought is applied. Scratchpad changed continuously while it was being used for research and we expect Axiom to do the same. The language (spad) is designed to let you write algorithms that are very close to the mathematics. However, the algorithms as presented in the current system have never been shown or proven (an important distinction) to be correct. It is vital that we undertake the huge effort of verifying and validating the code. How else can we trust the results and of what use is a system this complex without trust? Somehow we have to extend the system to integrate program proof techniques. That is, we have to make computational mathematics hold to the same standard as the rest of mathematics. All of which seems to integrate into a requirement for better documentation. The key change which developers of Axiom will find with this version is that the documentation is primary and the code is secondary. Taking direction from Knuth and Dijkstra the system is now in a literate programming style. The hope is that the next generation of developers and users will be able to understand, maintain and extend the system gracefully. And that eventually papers submitted to journals (an Axiom Journal?) will be easily imported into the system with their running code made available automatically. There is no guarantee that this attempt to change the culture of computational mathematicians is going to succeed. But it is our firm belief that current systems have reached a complexity plateau and we need to find new techniques to push the envelope. In general, we need to consider changes to the system with a 30 year horizon rather than the current write-ship-debug mentality of software development. This is, after all, mathematics, the queen of the sciences. It deserves all of the time, talent and attention we can bring to bear on the subject. Tim Daly -- September 3, 2002 Contributions All of these people have, in some way or other, been associated with Scratchpad and Axiom. If you contribute, add your name. The names are in alphabetical order as we make no attempt to quantify the relative merit of the contributions. In books/bookvol5.pamphlet is a variable called credits which contains this list. Typing )credits at the axiom command prompt will prettyprint the list. "An alphabetical listing of contributors to AXIOM:" Roy Adler Christian Aistleitner Michael Albaugh Cyril Alberga Jason Allen Richard Anderson George Andrews Jerry Archibald S.J. Atkins Jeremy Avigad Brent Baccala Knut Bahr Henry Baker Martin Baker Stephen Balzac Yurij Baransky David R. Barton Thomas Baruchel Gerald Baumgartner Gilbert Baumslag Michael Becker Nelson H. F. Beebe Jay Belanger Siddharth Bhat David Bindel Fred Blair Vladimir Bondarenko Ed Borasky Mark Botch Raoul Bourquin Alexandre Bouyer Karen Braman Wolfgang Brehm Peter A. Broadbery Martin Brock Manuel Bronstein Christopher Brown Stephen Buchwald Florian Bundschuh Luanne Burns William Burge Ralph Byers Quentin Carpent Jacques Carette Pierre Casteran Robert Cavines Pablo Cayuela Bruce Char Ondrej Certik Tzu-Yi Chen Bobby Cheng Cheekai Chin David V. Chudnovsky Gregory V. Chudnovsky Mark Clements Roland Coeurjoly Emil Cohen Hirsh Cohen Josh Cohen James Cloos Jia Zhao Cong Christophe Conil Don Coppersmith George Corliss Robert Corless Gary Cornell Frank Costa Meino Cramer Karl Crary Jeremy Du Croz David Cyganski Nathaniel Daly Timothy Daly Sr. Timothy Daly Jr. James H. Davenport David Day James Demmel Didier Deshommes Michael Dewar Inderjit Dhillon Jack Dongarra Jean Della Dora Gabriel Dos Reis Claire DiCrescendo Sam Dooley Pierre Doucy Nicolas James Doye Zlatko Drmac Lionel Ducos Iain Duff Lee Duhem Martin Dunstan Brian Dupee Dominique Duval Robert Edwards Hans-Dieter Ehrich Heow Eide-Goodman Alexandra Elbakyan Carl Engelman Lars Erickson Mark Fahey William Farmer Richard Fateman Bertfried Fauser Stuart Feldman John Fletcher Brian Ford Albrecht Fortenbacher George Frances Constantine Frangos Timothy Freeman Korrinn Fu Marc Gaetano Rudiger Gebauer Van de Geijn Kathy Gerber Patricia Gianni Eitan Gurari Gustavo Goertkin Samantha Goldrich Max Goldstein Holger Gollan Teresa Gomez-Diaz Ralph Gomory Laureano Gonzalez-Vega Stephen Gortler Johannes Grabmeier Matt Grayson Martin Griss Andrey G. Grozin Klaus Ebbe Grue James Griesmer Vladimir Grinberg Oswald Gschnitzer Ming Gu Fred Gustavson Jocelyn Guidry Gaetan Hache Steve Hague Satoshi Hamaguchi Sven Hammarling Mike Hansen Richard Hanson Richard Harke Joseph Harry Bill Hart Vilya Harvey Martin Hassner Arthur S. Hathaway Dan Hatton Waldek Hebisch Karl Hegbloom Ralf Hemmecke Tony Hearn Henderson Antoine Hersen Nicholas J. Higham Lou Hodes Alan Hoffman Hoon Hong Roger House Joris van der Hoeven Gernot Hueber Pietro Iglio Joan Jaffe Alejandro Jakubi Richard Jenks Bo Kagstrom William Kahan Kyriakos Kalorkoti Kai Kaminski Matt Kaufmann Grant Keady Tom Kelsey Wilfrid Kendall Tony Kennedy David Kincaid Keshav Kini Knut Korsvold Ted Kosan Paul Kosinski Igor Kozachenko Fred Krogh Klaus Kusche Bernhard Kutzler Tim Lahey Larry Lambe Magnus Larsson Kaj Laurson Charles Lawson George L. Legendre Franz Lehner Frederic Lehobey Michel Levaud Howard Levy J. Lewis Ren-Cang Li Xin Li John Lipson Rudiger Loos Craig Lucas Michael Lucks Richard Luczak Camm Maguire Dave Mainey Francois Maltey William Martin Ursula Martin Dan Martins Osni Marques Alasdair McAndrew Bob McElrath Michael McGettrick Roland McGrath Paul McJones Bob McNeill Edi Meier Ian Meikle David Mentre Simon Michael Jonathan Millen Victor S. Miller Gerard Milmeister William Miranker Mohammed Mobarak H. Michael Moeller Michael Monagan Marc Moreno-Maza Scott Morrison Joel Moses Mark Murray William Naylor Patrice Naudin C. Andrew Neff John Nelder Godfrey Nolan Arthur Norman Jinzhong Niu Michael O'Connor Summat Oemrawsingh Kostas Oikonomou Humberto Ortiz-Zuazaga Julian A. Padget Bill Page David Parnas Igor Pashev Norm Pass Susan Pelzel Michel Petitot Didier Pinchon Ayal Pinkus Frederick H. Pitts Frank Pfenning Erik Poll Jose Alfredo Portes E. Quintana-Orti Gregorio Quintana-Orti Beresford Parlett A. Petitet Andre Platzer Peter Poromaas Greg Puhak Claude Quitte Arthur C. Ralfs Norman Ramsey Anatoly Raportirenko Guilherme Reis Huan Ren Albert D. Rich Michael Richardson Jason Riedy Renaud Rioboo Robert Risch Wilken Rivera Jean Rivlin Nicolas Robidoux Simon Robinson Raymond Rogers Michael Rothstein Martin Rubey Jeff Rutter R.W Ryniker II Philip Santas Grigory Sarnitskiy David Saunders Aleksej Saushev Alfred Scheerhorn William Schelter Gerhard Schneider Martin Schoenert Marshall Schor Frithjof Schulze Fritz Schwartz Jens Axel Segaard Steven Segletes Srinivasan Seshan V. Sima Nick Simicich Peter Simons William Sit Elena Smirnova Jacob Nyffeler Smith Matthieu Sozeau Richard Stallman Ken Stanley William Stein Jonathan Steinbach Alexander Stepanov Doug Stewart Fabio Stumbo Christine Sundaresan Ben Collins-Sussman Klaus Sutner Robert Sutor Moss E. Sweedler Eugene Surowitz Yong Kiam Tan Max Tegmark T. Doug Telford James Thatcher Laurent Thery Balbir Thomas Mike Thomas Carol Thompson Simon Thompson Dylan Thurston Francoise Tisseur Steve Toleque Dick Toupin Raymond Toy Barry Trager Hale Trotter Themos T. Tsikas Gregory Vanuxem Kresimir Veselic Christof Voemel E.G. Wagner Bernhard Wall Justin Walker Paul Wang Stephen Watt Andreas Weber Jaap Weel Al Weis Juergen Weiss M. Weller Mark Wegman James Wen Thorsten Werther Michael Wester R. Clint Whaley James T. Wheeler John M. Wiley Berhard Will Clifton J. Williamson Stephen Wilson Shmuel Winograd Robert Wisbauer Sandra Wityak Waldemar Wiwianka Knut Wolf Hans Peter Wuermli Yanyang Xiao Liu Xiaojun Clifford Yapp David Yun Qian Yun Vadim Zhytnikov Paul Zimmermann Richard Zippel Wolfgang Zocher Evelyn Zoernack Bruno Zuercher Dan Zwillinger Pervasive Literate Programming I think David Diamond said it best (Datamation, June 1976, pg 134): The fellow who designed it is working far away. The spec's not been updated for many a livelong day. The guy who implemented it is promoted up the line. And some of the enhancements didn't match to the design. They haven't kept the flowcharts, the manual's a mess. And most of what you need to know, you'll simply have to guess. and with respect to Axiom: The research that it's based on is no longer to be had. And the theory that it's based on has changed by just a tad. If we keep it all together then at least there is a hope. That the people who maintain it will have a chance to cope. To quote Fred Brooks, "The Mythical Man-month" "A basic principle of data processing teaches the folly of trying to maintain independent files in synchronization... Yet our practice in programming documentation violates our own teaching. We typically attempt to maintain a machine-readable form of a program and an independent set of human-readable documentation, consisting of prose and flowcharts ... The solution, I think, is to merge the files, to incorporate the documentation in the source program." "A common fallacy is to assume authors of incomprehensilbe code will somehow be able to express themselves lucidly and clearly in comments." -- Kevlin Henney "A programmer who cannot explain their ideas clearly in natural language is incapable of writing readable code." -- Tim Daly As you can already see from this document the whole of the Axiom effort is structured around literate programs. Every directory has a Makefile.pamphlet file which explains details of that directory. The whole source tree hangs from the Makefile tree. (Some of the Makefile.pamphlet files contain only text if executable code is not needed). Every source file is embedded in a pamphlet file. Which begs the question: ``What is a pamphlet file?''. Basically it is a tex document with some additional markup tags that surround source code. Pamphlet files are intended to document one particular subject. Pamphlet files can be later combined into ``booklet'' files as one would embed chapters into books. Which begs the question: ``Why bother with pamphlet files?''. Clearly you didn't read the philosophy rant above. In more detail there have been two traditional methods of documenting source code. The first is to sprinkle random comments into the code. This suffers from the problem that the comments assume you already understand the purpose of the code and why an enlightened comment like ``This oughta work'' is perfectly clear and compelling. The second method is to write a document as a separate file. They get written half-heartedly because the lack of source code allows you to skip over explaining ugly implementation details (where all of the real confusion lies). This form of documentation never gets updated and gradually becomes uninteresting history. Pamphlet files overcome neither of these limitations if you don't make the effort to do it right. Ask yourself the question ``What would Knuth do?'' or ``Will this be clear 30 years from now?''. Which begs the question: ``Why go to all this trouble?''. Because you're having a conversation with people who are far removed from you in time, space, and understanding. Because someone else will have to maintain your code. Because you are part of a community of mathematicians who hold you to high standards. Because if you can't explain it clearly maybe YOU don't understand it or it isn't as clear as you think it is. Lets imagine that we'd like to receive a pamphlet file from a colleague. It contains a new theory and spiffy new algorithm. We'd like to be able to put the pamphlet file into the system and have everything magically happen to integrate the new pamphlet into the system. What would that imply? Well, lets assume that the pamphlet file has certain required sections. We'd like to get more than the technical paper and the code. We'd also like to see the help information, test cases, example code, cross-references to other pamphlets that would get automatically included, have the proof available and automatically checkable, etc. In the best of all possible worlds we have a front-end system that knows nothing except how to deconstruct and integrate properly formed pamphlet files. If this were true we could be sure that all of the mathematics is documented and external to the system. There are no ``rabbits'' (as Dijkstra called surprises or special knowledge) that we pull out of our hat. Conceptually, given an underlying Lisp system, it is clear we can built such a system. The General Directory Structure The Top Level directory structure contains 7 directories which are explained in detail below. Three of the directories (license, zips, and lsp) are not part of the essential core of Axiom. The other four directories (src, int, obj, and mnt) comprise the system build environment. Each directory has a specific purpose. Lets look at the essential directories first. $AXIOM license lsp GCL src include lib scripts int doc obj tmp noweb SYS=(linux,...) mnt SYS=(linux,...) zips The src directory consists of human-written, system-independent code. You can copy this directory (and the top-level makefiles) and have a complete build system. Nothing in this directory is ever changed by the Makefiles and it can be mounted in a read-only fashion during the build process. An example file would be the lisp source files. The int directory consists of machine-generated, system-independent code. Consider this directory as a cache. Nothing in this directory is necessary for a clean system build but once the build completes the information in this directory can significantly shorten rebuilds. Since this information is system-independent we can use the cache no matter what architecture we target. An example file would be the dvi files generated from the tex sources. The obj directory consists of machine-generated, system-dependent code. This directory is "scratch" space for the compiler and other tools. Nothing in this directory is useful once the system is built. An example file would be the .o files from the C compiler. The mnt directory consists of machine-generated, system-dependent code that will comprise the "shipped system". You can copy this directory and have a complete, running Axiom system. If the end user will see it or need it in any way it belongs here. Executables are generally built in obj and moved here. Example files would be the final executable images, the input files, etc. The four directories above make it possible to do a system build for one system (say, a linux system) which will fill in the int subdirectory. Then you can NFS mount the src and int directories read-only on a Solaris machine and do a solaris system build. The original Axiom could build across many different architectures, compilers, and operating systems. The license directory The license directory collects all of the licenses for material that is included in this distribution. Source files contain a line that refers to one of these license files. Some people are of the belief that including the full license text in every source file magically strengthens the license but this is not so. Imagine including the full text of the copyright at the beginning of every section of a book. The LICENSE.AXIOM file is a Modified BSD-style license that covers all of the files released as part of this distribution except as noted in particular files. Copyright information that might have shown up in source files that were released from NAG are also collected here and noted at the top of the files they cover. The zips directory The zips directory contains particular distributions of network-available software that is known to work with this release of Axiom. Newer versions may work and, if so, should be added to this directory. The makefiles that handle these files will unpack them into the correct locations in the src directory tree. These files exist to increase the stability of the distribution so we can guarantee that the code works. We encourage testing the latest distributions so that we can remain with the leading edge and give feedback to the individual package developers if problems arise. The lsp directory Axiom lives on top of Common Lisp, specifically Gnu Common Lisp (GCL) Steps to build Axiom The Initial Distribution files The initial distribution contains several top level files. These are: 1) Makefile.pamphlet This is the noweb source for the Makefile file. All changes to the Makefile should occur here and the 3) Makefile This is the actual Makefile that will create Axiom. In general the distribution will contain the pamphlet files for each source file and the source file itself. Modifications should be made and explained in the pamphlet files. The document command should be run to rebuild the source file and the dvi file. Steps in the build process The sequence of steps necessary to build a clean Axiom is simply: export AXIOM=(path-including-this-directory)/mnt/SYSNAME export PATH=$AXIOM/bin:$PATH make If this fails check the FAQ for possible problems and their fixes.
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Axiom is a free, open source computer algebra system
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