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\input texinfo @c ---------------------------------------------------------------------- @c $Id: redlog.texi,v 1.18 2004/05/04 17:12:51 sturm Exp $ @c ---------------------------------------------------------------------- @c Copyright (c) 1995-2004 Andreas Dolzmann and Thomas Sturm @c ---------------------------------------------------------------------- @c $Log: redlog.texi,v $ @c Revision 1.18 2004/05/04 17:12:51 sturm @c Quick switch to 3.0 as good as possible. @c @c Revision 1.17 2003/10/12 12:35:31 sturm @c Some corrections in the doc of pasf. @c Some doc on ibalp. @c @c Revision 1.16 2003/03/19 13:33:47 lasaruk @c First version of PASF-documentation added. @c @c Revision 1.15 2003/03/10 18:50:27 seidl @c Cared for PASF context and added TODO Lasaruk at several places. @c Removed READ THIS FIRST hack. Now the following simple commands should @c generate the desired info, dvi and html output: @c makeinfo redlog.texi @c tex redlog.texi @c texi2html -split_chapter -menu -expandinfo redlog.texi @c For the online manual, index.html can link now to redlog.html instead @c of redlog_toc.html. Other desired output forms have still to be looked @c after. @c @c Revision 1.14 2002/08/29 08:12:04 dolzmann @c Added description of local quantifier elimination. @c @c Revision 1.13 2002/01/18 12:39:26 sturm @c Addded documentation for CAD. @c @c Revision 1.12 1999/04/13 22:17:30 sturm @c Added remark on updates on the WWW page. @c @c Revision 1.11 1999/04/13 12:27:14 sturm @c Removed a blank line within @itemize. @c @c Revision 1.10 1999/04/11 12:50:32 sturm @c Removed reference to program documentation for now. @c @c Revision 1.9 1999/04/11 12:23:58 sturm @c Overworked once more. @c Better index. @c Ispelled again. @c @c Revision 1.8 1999/04/07 17:05:39 sturm @c Overworked chapter "Quantifier Elimination and Variants". @c Ispelled. @c @c Revision 1.7 1999/04/05 12:49:12 sturm @c Finished overworking chapter "Simplification". @c Overworked chapter "Normal Forms". @c Completely dropped chapter "Miscellaneous". @c @c Revision 1.6 1999/04/01 11:31:06 sturm @c Overworked chapter "Simplification" and changed indeces. @c @c Revision 1.5 1999/03/22 16:48:07 sturm @c Overworked chapter "Format and Handling of Formulas". There is only "Other @c Stuff" left in chapter "Miscellaneous" now. @c @c Revision 1.4 1999/03/22 14:33:20 sturm @c Updated references. @c Overworked Introduction. New section "Loading and Context Selection". @c @c Revision 1.3 1998/04/09 11:14:38 sturm @c Added documentation for switch rlqeqsc. @c @c Revision 1.2 1997/10/02 09:36:57 sturm @c Updated reference to simplification paper. @c @c Revision 1.1 1997/08/18 17:22:50 sturm @c Renamed "rl.texi" to this file "redlog.texi." @c Changes due to renaming "rl.red" to "redlog.red." @c @c ---------------------------------------------------------------------- @c Revision 1.20 1997/08/14 10:10:54 sturm @c Renamed rldecdeg to rldecdeg1. @c Added service rldecdeg. @c @c Revision 1.19 1996/10/23 12:03:05 sturm @c Added "exceptionlist" paramter to rlgqe and rlgqea. Several quantifier @c blocks are treated correctly now. @c @c Revision 1.18 1996/10/22 11:17:05 dolzmann @c Adapted the documentation of the procedures rlstruct, rlifstruct to @c the new interface. @c @c Revision 1.17 1996/10/20 15:57:46 sturm @c Added documentation for the switches rlnzden, rlposden, and rladdcond. @c Added documentation for the functions rlvarl, rlfvarl, and rlbvarl. @c @c Revision 1.16 1996/10/09 14:46:29 sturm @c Corrected @settitle. @c @c Revision 1.15 1996/10/09 11:41:04 sturm @c Some more minor changes. @c @c Revision 1.14 1996/10/08 17:41:58 sturm @c Overworked the whole thing more than once. @c @c Revision 1.13 1996/10/07 21:58:39 dolzmann @c Added data structure substitution_list. @c Added documentation for rlterml, rltermml, rlifacml, rltnf, rltnft, @c rlstruct, and rlifstruct. @c @c Revision 1.12 1996/10/07 18:39:08 reiske @c Revised and corrected documentation. @c Added documentation for rlqeipo, rlqews, and rlgentheo. @c Updated documentation for tableau and Groebner simplifier. @c Added documentation for data structure "cdl" and "elimination_answer". @c @c Revision 1.11 1996/09/26 13:05:17 dolzmann @c Minor changes in description of rltab. @c @c Revision 1.10 1996/09/26 12:14:27 sturm @c Corrected wrong citation label. @c @c Revision 1.9 1996/08/01 12:05:18 reiske @c Added documentation for rlifacl and rlapnf. @c @c Revision 1.8 1996/07/14 10:04:54 dolzmann @c Updated documentation of the Groebner simplifier. @c @c Revision 1.7 1996/06/13 10:03:45 sturm @c Added documentation for data structure "theory" and for procedures @c "sub" and "rlgqe". @c Moved "rlopt" into the Chapter on QE. @c @c Revision 1.6 1996/03/12 12:55:55 sturm @c Changed title to "Redlog User Manual." @c Many changes in introductory sections: Added functionality overview, @c "Getting Started", modified the "Bug Report" section, introduced the @c notion of a "context." @c Corrected example in the description of rlpnf. @c Many changes in QE documentation chapter. @c Added documentation for data structure "multiplicity list", switch @c rlqeheu, and functions rlmatrix, rlatl, and rlatml. @c Added a "Data Structure Index." @c Added new (bibliographic) reference. @c @c Revision 1.5 1996/03/04 14:50:26 dolzmann @c Added description of switches rlgserf, rlbnfsac. @c Removed description of switch rlbnfsb. @c @c Revision 1.4 1996/02/18 15:56:46 sturm @c Adapted the documentation of rlsiexpla to new default setting T. @c @c Revision 1.3 1996/02/18 15:16:48 sturm @c Added references. @c Added introductions to chapters on QE and optimization. @c Added concept index. @c Added description of input facilities. @c Modified description of switch rlqedfs. @c Added description of switches rlbnfsb, rlbnfsm, rlsifac, rlsimpl, @c rlsipw, rlsipo. @c @c Revision 1.2 1995/08/30 07:29:18 sturm @c Many changes. Version passed to R.O.S.E. with the rl demo. @c @c Revision 1.1 1995/07/17 14:33:33 sturm @c Initial check-in. @c @c ---------------------------------------------------------------------- @setfilename redlog.info @settitle @sc{redlog} User Manual @c @setchapternewpage off @smallbook @defcodeindex rf @defcodeindex rv @defcodeindex rt @ifinfo This is the documentation of @sc{redlog}, a @sc{reduce} logic package. Copyright @copyright{} 1995-2004 by A. Dolzmann, A. Seidl, and T. Sturm. @end ifinfo @titlepage @title{Redlog User Manual} @subtitle A @sc{reduce} Logic Package @subtitle Edition 3.0, for @sc{redlog} Version 3.0 (@sc{reduce} 3.8) @subtitle 15 April 2004 @author by A. Dolzmann, A. Seidl, and T. Sturm @page @vskip 0pt plus 1filll Copyright @copyright{} 1995-2004 by A. Dolzmann, A. Seidl, and T. Sturm. @end titlepage @ifnottex @node Top @top REDLOG @heading REDLOG @sc{redlog} is a @sc{reduce} package containing algorithms on first-order formulas. The current version is 3.0. @end ifnottex @heading Acknowledgments We acknowledge with pleasure the superb support by Herbert Melenk and Winfried Neun of the Konrad-Zuse-Zentrum fuer Informationstechnik Berlin, Germany, during this project. Furthermore, we wish to mention numerous valuable mathematical ideas contributed by Volker Weispfenning, University of Passau, Germany. @heading Redlog Home Page @cindex @sc{www} @cindex home page There is a @sc{redlog} home page maintained at @center @t{http://www.fmi.uni-passau.de/~redlog/}. It contains information on @sc{redlog}, online versions of publications, and a collection of examples that can be computed with @sc{redlog}. This site will also be used for providing update @cindex update versions of @sc{redlog}. @heading Support @cindex support For mathematical and technical support, contact @center @t{redlog@@fmi.uni-passau.de}. @heading Bug Reports and Comments @cindex bug report Send bug reports and comments to @center @t{redlog@@fmi.uni-passau.de}. Any hint or suggestion is welcome. In particular, we are interested in practical problems to the solution of which @sc{redlog} has contributed. @menu * Introduction:: What is @sc{redlog}? * Loading and Context Selection:: * Format and Handling of Formulas:: How to work with formulas. * Simplification:: Standard, tableau, and Groebner. * Normal Forms:: CNF, DNF, NNF, and PNF. * Quantifier Elimination and Variants:: Elimination set methods. * References:: Further information on @sc{redlog}. * Functions:: * Switches and Variables:: * Data Structures:: * Index:: @end menu @node Introduction @chapter Introduction @sc{redlog} stands for @emph{@sc{reduce} logic system}. It provides an extension of the computer algebra system @sc{reduce} to a @emph{computer logic system} implementing symbolic algorithms on first-order formulas wrt.@: temporarily fixed first-order languages and theories. This document serves as a user guide describing the usage of @sc{redlog} from the algebraic mode of @sc{reduce}. For a detailed description of the system design see @ifinfo @ref{References,[DS97a]}. @end ifinfo @iftex [DS97a]. @end iftex @c There is an additional program documentation included in the @sc{reduce} @c distribution. An overview on some of the application areas of @sc{redlog} is given in @ifinfo @ref{References,[DSW98]}. @end ifinfo @iftex [DSW98]. @end iftex See also @ref{References} for articles on @sc{redlog} applications. @menu * Contexts:: * Overview:: * Conventions:: @end menu @node Contexts @section Contexts @cindex real numbers @cindex complex numbers @cindex p-adic number @cindex real closed field @cindex ordered field @cindex real closed field @cindex discretely valued field @cindex algebraically closed field @cindex contexts available @cindex available contexts @cindex @sc{ofsf} @cindex @sc{acfsf} @cindex @sc{dvfsf} @sc{redlog} is designed for working with several @dfn{languages} and @dfn{theories} in the sense of first-order logic. Both a language and a theory make up a context. In addition, a context determines the internal representation of terms. There are the following contexts available: @table @sc @item ofsf @sc{of} stands for @emph{ordered fields}, which is a little imprecise. The quantifier elimination actually requires the more restricted class of @emph{real closed fields}, while most of the tool-like algorithms are generally correct for ordered fields. One usually has in mind real numbers with ordering when using @sc{ofsf}. @item dvfsf @emph{Discretely valued fields}. This is for computing with formulas over classes of p-adic valued extension fields of the rationals, usually the fields of p-adic numbers for some prime p. @item acfsf @emph{Algebraically closed fields} such as the complex numbers. @item pasf @emph{Presssburger Arithmetic}, i.e., the linear theory of integers with congruences modulo @tex $m$ @end tex @ifinfo m @end ifinfo for @tex $m\geq2$ @end tex @ifinfo m>=2 @end ifinfo . @item ibalp @emph{Initial Boolean algebras}, basically quantified propositional logic. @item dcfsf @emph{Differentially closed fields} according to Robinson. There is no natural example. The quantifier elimination is an optimized version of the procedure by Seidenber (1956). @end table The trailing "@sc{-sf}" stands for @emph{standard form}, which is the representation chosen for the terms within the implementation. Accordingly, "@sc{-lp}" stands for @emph{Lisp prefix}. @xref{Context Selection}, for details on selecting @sc{redlog} contexts. @node Overview @section Overview @sc{redlog} origins from the implementation of quantifier elimination procedures. Successfully applying such methods to both academic and real-world problems, the authors have developed over the time a large set of formula-manipulating tools, many of which are meanwhile interesting in their own right: @itemize @bullet @item Numerous tools for comfortably inputing, decomposing, and analyzing formulas. This includes, for instance, the construction of systematic formulas via @code{for}-loops, and the extension of built-in commands such as @code{sub} @rfindex sub or @code{part}. @rfindex part @xref{Format and Handling of Formulas}. @item Several techniques for the @emph{simplification} of formulas. The simplifiers do not only operate on the boolean structure of the formulas but also discover algebraic relationships. For this purpose, we make use of advanced algebraic concepts such as Groebner basis computations. For the notion of simplification and a detailed description of the implemented techniques for the contexts @sc{ofsf} @cindex @sc{ofsf} and @sc{acfsf} @cindex @sc{acfsf} see @ifinfo @ref{References,[DS97]}. @end ifinfo @iftex [DS97]. @end iftex For the @sc{dvfsf} @cindex @sc{dvfsf} context see @ifinfo @ref{References,[DS99]}. @end ifinfo @iftex [DS99]. @end iftex @xref{Simplification}. @item Various @emph{normal form computations}. The @emph{@sc{cnf}/@sc{dnf}} computation includes both boolean and algebraic simplification strategies @ifinfo @ref{References,[DS97]}. @end ifinfo @iftex [DS97]. @end iftex The @emph{prenex normal form} computation minimizes the number of quantifier changes. @xref{Normal Forms}. @item @cindex comprehensive Groebner Basis @cindex @sc{cgb} @emph{Quantifier elimination} computes quantifier-free equivalents for given first-order formulas. For @sc{ofsf} and @cindex @sc{ofsf} @sc{dvfsf} @cindex @sc{dvfsf} we use a technique based on elimination set ideas @ifinfo @ref{References,[Wei88]}. @end ifinfo @iftex [Wei88]. @end iftex The @sc{ofsf} @cindex @sc{ofsf} implementation is restricted to at most quadratic occurrences of the quantified variables, but includes numerous heuristic strategies for coping with higher degrees. See @ifinfo @ref{References,[LW93]}, @ref{References,[Wei97]}, @end ifinfo @iftex [LW93], [Wei97] @end iftex for details on the method. The @sc{dvfsf} @cindex @sc{dvfsf} implementation is restricted to formulas that are linear in the quantified variables. The method is described in detail in @ifinfo @ref{References,[Stu00]}. @end ifinfo @iftex [Stu00]. @end iftex The @sc{acfsf} @cindex @sc{acfsf} quantifier elimination is based on @emph{comprehensive Groebner basis} computation. There are no degree restrictions for this context @ifinfo @ref{References,[Wei92]}. @end ifinfo @iftex [Wei92]. @end iftex @xref{Quantifier Elimination}. @item @cindex geometric problem @cindex network analysis The contexts @sc{ofsf} @cindex @sc{ofsf} and @sc{acfsf} @cindex @sc{acfsf} allow a variant of quantifier elimination called @dfn{generic quantifier elimination} @ifinfo @ref{References,[DSW98]}. @end ifinfo @iftex [DSW98]. @end iftex There are certain non-degeneracy assumptions made on the parameters, which considerably speeds up the elimination. For geometric theorem proving it has turned out that these assumptions correspond to reasonable geometric non-degeneracy conditions @ifinfo @ref{References,[DSW98]}. @end ifinfo @iftex [DSW98]. @end iftex Generic quantifier elimination has turned out useful also for physical applications such as network analysis @ifinfo @ref{References,[Stu97]}. @end ifinfo @iftex [Stu97]. @end iftex There is no generic quantifier elimination available for @sc{dvfsf}. @cindex @sc{dvfsf} @xref{Generic Quantifier Elimination}. @item The contexts @sc{ofsf} @cindex @sc{ofsf} and @sc{dvfsf} @cindex @sc{dvfsf} provide variants of (generic) quantifier elimination that additionally compute @dfn{answers} @cindex answer such as satisfying sample points for existentially quantified formulas. This has been referred to as the "extended quantifier elimination problem" @ifinfo @ref{References,[Wei97a]}. @end ifinfo @iftex [Wei97a]. @end iftex @xref{Quantifier Elimination}. @item @sc{ofsf} @cindex @sc{ofsf} includes linear @emph{optimization} techniques based on quantifier elimination @ifinfo @ref{References,[Wei94a]}. @end ifinfo @iftex [Wei94a]. @end iftex @xref{Linear Optimization}. @end itemize @node Conventions @section Conventions To avoid ambiguities with other packages, all @sc{redlog} functions and switches are prefixed by "@code{rl}". The remaining part of the name is explained by the first sentence of the documentation of the single functions and switches. Some of the numerous switches of @sc{redlog} have been introduced only for finding the right fine tuning of the functions, or for internal experiments. They should not be changed anymore, except for in very special situations. For an easier orientation the switches are divided into three categories for documentation: @table @dfn @item Switch @cindex switch This is an ordinary switch, which usually selects strategies appropriate for a particular input, or determines the required trade-off between computation-speed and quality of the result. @item Advanced Switch @cindex advanced Switch They are used like ordinary switches. You need, however, a good knowledge about the underlying algorithms for making use of it. @item Fix Switch @cindex fix Switch You do not want to change it. @end table @node Loading and Context Selection @chapter Loading and Context Selection @cindex starting @sc{redlog} @menu * Loading Redlog:: * Context Selection:: @end menu @node Loading Redlog @section Loading Redlog @cindex loading @sc{redlog} At the beginning of each session @sc{redlog} has to be loaded explicitly. This is done by inputing the command @code{load_package redlog;} @rfindex load_package from within a @sc{reduce} session. @node Context Selection @section Context Selection @cindex theory @cindex language @cindex relations @cindex predicates @cindex functions Fixing a context reflects the mathematical fact that first-order formulas are defined over fixed @dfn{languages} specifying, e.g., valid @dfn{function symbols} and @dfn{relation symbols} (@dfn{predicates}). After selecting a language, fixing a @dfn{theory} such as "the theory of ordered fields", allows to assign a semantics to the formulas. Both language and theory make up a @sc{redlog} context. In addition, a context determines the internal representation of terms. As first-order formulas are not defined unless the language is known, and meaningless unless the theory is known, it is impossible to enter a first-order formula into @sc{redlog} without specifying a context: @smallexample REDUCE 3.6, 15-Jul-95, patched to 30 Aug 98 ... 1: load_package redlog; 2: f := a=0 and b=0; ***** select a context @end smallexample @xref{Contexts}, for a summary of the available contexts @sc{ofsf}, @cindex @sc{ofsf} @sc{dvfsf}, @cindex @sc{dvfsf} and @sc{acfsf}. @cindex @sc{acfsf} A context can be selected by the @code{rlset} command: @deffn {Function} rlset [@var{context} [@var{arguments}...]] @deffnx {Function} rlset argument-list @cindex language selection @cindex context selection @rtindex dvf_class_specification Set current context. Valid choices for @var{context} are @sc{ofsf} @cindex @sc{ofsf} (ordered fields standard form), @sc{dvfsf} @cindex @sc{dvfsf} (discretely valued fields standard form), @sc{acfsf} @cindex @sc{acfsf} (algebraically closed fields standard form), @sc{pasf} @cindex @sc{pasf} (Presburger arithmetic standard form), @sc{ibalp} @cindex @sc{ibalp} (initial Boolean algebra Lisp prefix), and @sc{dcfsf} @cindex @sc{dcfsf} . With @sc{ofsf}, @sc{acfsf}, @sc{pasf}, @sc{ibalp}, and @sc{dcfsf} there are no further arguments. With @sc{dvfsf} an optional @var{dvf_class_specification} can be passed, which defaults to @code{0}. @code{rlset} returns the old setting as a list that can be saved to be passed to @code{rlset} later. When called with no arguments (or the empty list), @code{rlset} returns the current setting. @end deffn @deftp {Data Structure} {dvf_class_specification} @cindex p-adic number @cindex p-adic valuation @cindex valuation (p-adic) @cindex valued field @cindex discretely valued field Zero, or a possibly negative prime @tex $q$. @end tex @ifinfo q. @end ifinfo For @tex $q=0$ @end tex @ifinfo q=0 @end ifinfo all computations are uniformly correct for all @tex $p$-adic @end tex @ifinfo p-adic @end ifinfo valuations. Both input and output then possibly involve a symbolic constant @tex "$p$", @end tex @ifinfo "p", @end ifinfo which is being reserved. For positive @tex $q$, @end tex @ifinfo q, @end ifinfo all computations take place wrt.@: the corresponding @tex $q$-adic @end tex @ifinfo q-adic @end ifinfo valuation. For negative @tex $q$, @end tex @ifinfo q, @end ifinfo the @tex "$-$" @end tex @ifinfo "-" @end ifinfo can be read as ``up to'', i.e., all computations are performed in such a way that they are correct for all @tex $p$-adic @end tex @ifinfo p-adic @end ifinfo valuations with @tex $p \leq |q|$. @end tex @ifinfo p <= q. @end ifinfo In this case, the knowledge of an upper bound for @tex $p$ @end tex @ifinfo p @end ifinfo supports the quantifier elimination @code{rlqe}/@code{rlqea} @rfindex rlqe @rfindex rlqea @ifinfo @ref{References,[Stu00]}. @end ifinfo @iftex [Stu00]. @end iftex @xref{Quantifier Elimination}. @end deftp The user will probably have a "favorite" context reflecting their particular field of interest. To save the explicit declaration of the context with each session, @sc{redlog} provides a global variable @code{rldeflang}, which contains a default context. This variable can be set already @emph{before} loading @file{redlog}. This is typically done within the @file{.reducerc} profile: @cindex @file{.reducerc} profile @example lisp (rldeflang!* := '(ofsf)); @end example Notice that the Lisp list representation has to be used here. @defvr Fluid rldeflang!* @cindex language default @cindex default language @cindex context default @cindex default context Default language. This can be bound to a default context before loading @file{redlog}. More precisely, @code{rldeflang!*} contains the arguments of @code{rlset} as a Lisp list. If @code{rldeflang!*} is non-nil, @code{rlset} @rfindex rlset is automatically executed on @code{rldeflang!*} when loading @file{redlog}. @end defvr In addition, @sc{redlog} evaluates an environment variable @code{RLDEFLANG}. This allows to fix a default context within the shell already before starting @sc{reduce}. The syntax for setting environment variables depends on the shell. For instance, in the @sc{gnu} Bash or in the csh shell one would say @code{export RLDEFLANG=ofsf} or @code{setenv RLDEFLANG ofsf}, respectively. @defvr {Environment Variable} RLDEFLANG @cindex language default @cindex default language @cindex context default @cindex default context Default language. This may be bound to a context in the sense of the first argument of @code{rlset}. @rfindex rlset With @code{RLDEFLANG} set, any @code{rldeflang!*} @rvindex rldeflang!* binding is overloaded. @end defvr @node Format and Handling of Formulas @chapter Format and Handling of Formulas After loading @sc{redlog} and selecting a context (@pxref{Loading and Context Selection}), there are @emph{first-order formulas} available as an additional type of symbolic expressions. That is, formulas are now subject to symbolic manipulation in the same way as, say, polynomials or matrices in conventional systems. There is nothing changed in the behavior of the builtin facilities and of other packages. @menu * First-order Operators:: * Closures:: * OFSF Operators:: * DVFSF Operators:: * ACFSF Operators:: * PASF Operators:: * IBALP Operators:: * DCFSF Operators:: * Extended Built-in Commands:: * Global Switches:: * Basic Functions on Formulas:: @end menu @node First-order Operators @section First-order Operators Though the operators @code{and}, @code{or}, and @code{not} are already sufficient for representing boolean formulas, @sc{redlog} provides a variety of other boolean operators for the convenient mnemonic input of boolean formulas. @deffn {Unary Operator} not @deffnx {n-ary Infix Operator} and @deffnx {n-ary Infix Operator} or @deffnx {Binary Infix Operator} impl @deffnx {Binary Infix Operator} repl @deffnx {Binary Infix Operator} equiv @cindex negation @cindex conjunction @cindex disjunction @cindex implication @cindex replication @cindex equivalence @cindex expression input @cindex input facilities @cindex boolean operator The infix operator precedence is from strongest to weakest: @code{and}, @code{or}, @code{impl}, @code{repl}, @code{equiv}. @end deffn @xref{Extended Built-in Commands}, for the description of extended @code{for}-loop @rfindex for actions that allow to comfortably input large systematic conjunctions and disjunctions. @sc{reduce} expects the user to know about the precedence of @code{and} over @code{or}. In analogy to @code{+} and @code{*}, there are thus no parentheses output around conjunctions within disjunctions. The following switch causes such subformulas to be bracketed anyway. @xref{Conventions}, for the notion of a "fix switch". @defvr {Fix Switch} rlbrop @cindex bracket @cindex expression output Bracket all operators. By default this switch is on, which causes some private printing routines to be called for formulas: All subformulas are bracketed completely making the output more readable. @end defvr Besides the boolean operators introduced above, first-order logic includes the well-known @dfn{existential quantifiers} and @dfn{universal quantifiers} @tex "$\exists$" and "$\forall$". @end tex @ifinfo "@emph{exists}" and "@emph{forall}". @end ifinfo @deffn {Binary Operator} ex @deffnx {Binary Operator} all @cindex quantifier @cindex expression input @cindex input facilities These are the @dfn{quantifiers}. The first argument is the quantified variable, the second one is the matrix formula. Optionally, one can input a list of variables as first argument. This list is expanded into several nested quantifiers. @end deffn @xref{Closures}, for automatically quantifying all variables except for an exclusion list. For convenience, we also have boolean constants @cindex boolean constant for the truth values. @cindex truth value @defvar true @defvarx false @cindex truth value @cindex expression input @cindex input facilities These algebraic mode variables are reserved. They serve as @dfn{truth values}. @end defvar @node Closures @section Closures @cindex closure @defun rlall formula [@var{exceptionlist}] @cindex universal closure @cindex closure @cindex quantifier @cindex expression input @cindex input facilities Universal closure. @var{exceptionlist} is a list of variables empty by default. Returns @var{formula} with all free variables universally quantified, except for those in @var{exceptionlist}. @end defun @defun rlex formula [@var{exceptionlist}] @cindex existential closure @cindex closure @cindex quantifier @cindex expression input @cindex input facilities Existential closure. @var{exceptionlist} is a list of variables empty by default. Returns @var{formula} with all free variables existentially quantified, except for those in @var{exceptionlist}. @end defun @node OFSF Operators @section OFSF Operators @cindex ordered field The @sc{ofsf} @cindex @sc{ofsf} context implements @emph{ordered fields} over the language of @emph{ordered rings}. Proceeding this way is very common in model theory since one wishes to avoid functions which are only partially defined, such as division in the language of ordered fields. Note that the @sc{ofsf} quantifier elimination procedures @cindex quantifier elimination (@pxref{Quantifier Elimination and Variants}) for non-linear formulas actually operate over @cindex real closed field @emph{real closed fields}. See @ref{Contexts} and @ref{Context Selection} for details on contexts. @deffn {Binary Infix operator} equal @deffnx {Binary Infix operator} neq @deffnx {Binary Infix operator} leq @deffnx {Binary Infix operator} geq @deffnx {Binary Infix operator} lessp @deffnx {Binary Infix operator} greaterp @cindex equation @cindex inequality @cindex ordering @cindex expression input @cindex input facilities The above operators may also be written as @code{=}, @code{<>}, @code{<=}, @code{>=}, @code{<}, and @code{>}, respectively. For @sc{ofsf} @cindex @sc{ofsf} there is specified that all right hand sides must be zero. Non-zero right hand sides in the input are hence subtracted immediately to the corresponding left hand sides. There is a facility to input @emph{chains} @cindex chains of binary relations of the above relations, which are also expanded immediately: @smallexample a<>b<c>d=f @result{} a-b <> 0 and b-c < 0 and c-d > 0 and d-f = 0 @end smallexample Here, only adjacent terms are related to each other. @end deffn Though we use the language of ordered rings, the input of integer reciprocals is allowed and treated correctly interpreting them as constants for rational numbers. @cindex rational numbers There are two switches that allow to input arbitrary reciprocals, which are then resolved into proper formulas in various reasonable ways. The user is welcome to experiment with switches like the following, which are not marked as @emph{fix switches}. @xref{Conventions}, for the classification of @sc{redlog} switches. @defvr Switch rlnzden @defvrx Switch rlposden @cindex inverse @cindex reciprocal @cindex division @cindex denominator @cindex parametric denominator Non-zero/positive denominators. Both switches are off by default. If both @code{rlnzden} and @code{rlposden} are on, the latter is active. Activating one of them, allows the input of reciprocal terms. With @code{rlnzden} on, these terms are assumed to be non-zero, and resolved by multiplication. When occurring with ordering relations the reciprocals are resolved by multiplication with their square preserving the sign. @smallexample (a/b)+c=0 and (a/d)+c>0; 2 @result{} a + b*c = 0 and a*d + c*d > 0 @end smallexample Turning @code{rlposden} on, guarantees the reciprocals to be strictly positive which allows simple, i.e.@: non-square, multiplication also with ordering relations. @smallexample (a/b)+c=0 and (a/d)+c>0; @result{} a + b*c = 0 and a + c*d > 0 @end smallexample @end defvr The non-zeroness or positivity assumptions made by using the above switches can be stored in a variable, and then later be passed as a @var{theory} @rtindex theory (@pxref{Standard Simplifier,theory}) to certain @sc{redlog} procedures. Optionally, the system can be forced to add them to the formula at the input stage: @defvr Switch rladdcond @cindex inverse @cindex reciprocal @cindex division Add condition. This is off by default. With @code{rladdcond} on, non-zeroness and positivity assumptions made due to the switches @code{rlnzden} and @code{rlposden} @rvindex rlnzden @rvindex rlposden are added to the formula at the input stage. With @code{rladdcond} and @code{rlposden} on we get for instance: @smallexample (a/b)+c=0 and (a/d)+c>0; @result{} (b <> 0 and a + b*c = 0) and (d > 0 and a + c*d > 0) @end smallexample @end defvr @node DVFSF Operators @section DVFSF Operators @cindex discretely valued field Discretely valued fields are implemented as a one-sorted language using the operators @code{|}, @code{||}, @code{~}, and @code{/~}, which encode @tex $\leq$, $<$, $=$, and $\neq$ @end tex @ifinfo @code{<=}, @code{<}, @code{=}, and @code{<>} @end ifinfo in the value group, respectively. For details see @ifinfo @ref{References,[Wei88]}, @ref{References,[Stu00]}, or @ref{References,[DS99]}. @end ifinfo @iftex [Wei88], [Stu00], or [DS99]. @end iftex @deffn {Binary Infix operator} equal @deffnx {Binary Infix operator} neq @deffnx {Binary Infix operator} div @deffnx {Binary Infix operator} sdiv @deffnx {Binary Infix operator} assoc @deffnx {Binary Infix operator} nassoc @cindex equation @cindex inequality @cindex divisibility @cindex strict divisibility @cindex weak divisibility @cindex expression input @cindex input facilities The above operators may also be written as @code{=}, @code{<>}, @code{|}, @code{||}, @code{~}, and @code{/~}, respectively. Integer reciprocals in the input are resolved correctly. @sc{dvfsf} @cindex @sc{dvfsf} allows the input of @emph{chains} @cindex chains of binary relations in analogy to @sc{ofsf}. @cindex @sc{ofsf} @xref{OFSF Operators}, for details. @end deffn With the @sc{dvfsf} @cindex @sc{dvfsf} operators there is no treatment of parametric denominators available. @cindex denominator @cindex parametric denominator @node ACFSF Operators @section ACFSF Operators @deffn {Binary Infix operator} equal @deffnx {Binary Infix operator} neq @cindex equation @cindex inequality @cindex expression input @cindex input facilities @cindex @sc{acfsf} The above operators may also be written as @code{=}, @code{<>}. As for @sc{ofsf}, @cindex @sc{ofsf} it is specified that all right hand sides must be zero. In analogy to @sc{ofsf}, @sc{acfsf} allows also the input of @emph{chains} @cindex chains of binary relations and an appropriate treatment of parametric denominators @cindex denominator @cindex parametric denominator in the input. @xref{OFSF Operators}, for details. @end deffn Note that the switch @code{rlposden} @rvindex rlposden (@pxref{OFSF Operators}) makes no sense for algebraically closed fields. @node PASF Operators @section PASF Operators @deffn {Binary Infix operator} equal @deffnx {Binary Infix operator} neq @deffnx {Binary Infix operator} leq @deffnx {Binary Infix operator} geq @deffnx {Binary Infix operator} lessp @deffnx {Binary Infix operator} greaterp @cindex equation @cindex inequality @cindex ordering @cindex congruence @cindex expression input @cindex input facilities The above operators may also be written as @code{=}, @code{<>}, @code{<=}, @code{>=}, @code{<}, and @code{>}, respectively. @deffnx {Ternary Prefix operator} cong @deffnx {Ternary Prefix operator} ncong The operators cong and ncong represent congruences with nonparametric modulus. As for @sc{ofsf}, @cindex @sc{ofsf} it is specified that all right hand sides must be zero. In analogy to @sc{ofsf}, @sc{pasf} allows also the input of @emph{chains} @cindex chains of binary relations in the input. @xref{OFSF Operators}, for details. @end deffn @node IBALP Operators @section IBALP Operators @deffn {Unary operator} bnot @deffnx {n-ary Infix operator} band @deffnx {n-ary Infix operator} bor @deffnx {Binary Infix operator} bimpl @deffnx {Binary Infix operator} brepl @deffnx {Binary Infix operator} bequiv @cindex Boolean not @cindex Boolean and @cindex Boolean or @cindex Boolean implication @cindex Boolean replication @cindex Boolean equivalence The operator @code{bnot} may also be written as @code{~}. The operators @code{band} and @code{bor} may also be written as @code{&} and @code{|}, resp. The operators @code{bimpl}, @code{brepl}, and @code{bequiv} may be written as @code{->}, @code{<-}, and @code{<->}, resp. @end deffn @deffn {Binary Infix operator} equal @cindex equation The operator @code{equal} may also be written as @code{=}. @end deffn @node DCFSF Operators @section DCFSF Operators @deffn {Binary Infix operator} d @cindex derivation The operator @code{d} denotes (higher) derivatives in the sense of differential algebra. For instance, the differential equation @ifinfo @example x'^2 + x = 0 @end example @end ifinfo @tex $$x'^2+x=0$$ @end tex is input as @code{x d 1 ** 2 + x = 0}. @code{d} binds stronger than all other operators. @end deffn @deffn {Binary Infix operator} equal @deffnx {Binary Infix operator} neq @cindex equation @cindex inequality The operator @code{equal} may also be written as @code{=}. The operator @code{neq} may also be written as @code{<>}. @end deffn @node Extended Built-in Commands @section Extended Built-in Commands Systematic conjunctions and disjunctions can be constructed in the algebraic mode in analogy to, e.g., @code{for ... sum ...}: @deffn {for loop action} mkand @deffnx {for loop action} mkor @findex for @cindex conjunction @cindex disjunction @cindex for loop action @cindex expression input @cindex input facilities Make and/or. Actions for the construction of large systematic conjunctions/disjunctions via for loops. @smallexample for i:=1:3 mkand for j:=1:3 mkor if j<>i then mkid(x,i)+mkid(x,j)=0; @result{} true and (false or false or x1 + x2 = 0 or x1 + x3 = 0) and (false or x1 + x2 = 0 or false or x2 + x3 = 0) and (false or x1 + x3 = 0 or x2 + x3 = 0 or false) @end smallexample @end deffn Here the truth values @cindex truth value come into existence due to the internal implementation of @code{for}-loops. They are always neutral in their context, and can be easily removed via simplification (@pxref{Standard Simplifier,function rlsimpl}, @pxref{Global Switches,switch rlsimpl}). The @sc{reduce} substitution command @code{sub} @rfindex sub can be applied to formulas using the usual syntax. @deftp {Data Structure} {substitution_list} @var{substitution_list} is a list of equations each with a kernel left hand side. @end deftp @defun sub substitution_list formula @cindex substitution @rtindex substitution_list Substitute. Returns the formula obtained from @var{formula} by applying the substitutions given by @var{substitution_list}. @smallexample sub(a=x,ex(x,x-a<0 and all(x,x-b>0 or ex(a,a-b<0)))); @result{} ex x0 ( - x + x0 < 0 and all x0 ( - b + x0 > 0 or ex a (a - b < 0))) @end smallexample @code{sub} works in such a way that equivalent formulas remain equivalent after substitution. In particular, quantifiers are treated correctly. @end defun @defun part formula n1 [n2 [n3...]] Extract a part. The @code{part} of @var{formula} is implemented analogously to that for built-in types: in particular the 0th part is the operator. @end defun @iftex Compare @code{rlmatrix} (@pxref{Basic Functions on Formulas}) @end iftex @ifinfo @xref{Basic Functions on Formulas,rlmatrix}, @end ifinfo @rfindex rlmatrix for extracting the @emph{matrix part} of a formula, i.e., removing @emph{all} initial quantifiers. @defun length formula @cindex length Length of @var{formula}. This is the number of arguments to the top-level operator. The length is of particular interest with the n-ary operators @code{and} @rfindex and and @code{or}. @rfindex or Notice that @code{part(@var{formula},length(@var{formula}))} @rfindex part is the part of largest index. @end defun @node Global Switches @section Global Switches There are three global switches that do not belong to certain procedures, but control the general behavior of @sc{redlog}. @defvr Switch rlsimpl @cindex automatic simplification @cindex simplification Simplify. By default this switch is off. With this switch on, the function @code{rlsimpl} @rfindex rlsimpl is applied at the expression evaluation stage. @xref{Standard Simplifier, rlsimpl}. @end defvr Automatically performing formula simplification at the evaluation stage is very similar to the treatment of polynomials or rational functions, which are converted to some normal form. @cindex normal form For formulas, however, the simplified equivalent is by no means canonical. @defvr {Switch} rlrealtime @cindex real time @cindex time @cindex wall clock time Real time. By default this switch is off. If on it protocols the wall clock time needed for @sc{redlog} commands in seconds. In contrast to the built-in @code{time} @rvindex time switch, the time is printed @emph{above} the result. @end defvr @defvr {Advanced Switch} rlverbose @cindex verbosity output @cindex protocol Verbose. By default this switch is off. It toggles verbosity output with some @sc{redlog} procedures. The verbosity output itself is not documented. @end defvr @node Basic Functions on Formulas @section Basic Functions on Formulas @defun rlatnum formula @cindex count atomic formulas @cindex number of atomic formulas @cindex atomic formulas Number of atomic formulas. Returns the number of atomic formulas contained in @var{formula}. Mind that truth values @cindex truth value are not considered atomic formulas. @end defun @deftp {Data Structure} {multiplicity_list} A list of 2-element-lists containing an object and the number of its occurrences. Names of functions returning @var{multiplicity_lists} typically end on "ml". @end deftp @defun rlatl formula @cindex atomic formula list @cindex list of atomic formulas @cindex set of atomic formulas @cindex atomic formulas List of atomic formulas. Returns the set of atomic formulas contained in @var{formula} as a list. @end defun @defun rlatml formula @cindex atomic formula multiplicity list @cindex multiplicity list of atomic formulas @cindex atomic formulas @rtindex multiplicity_list Multiplicity list of atomic formulas. Returns the atomic formulas contained in @var{formula} in a @var{multiplicity_list}. @end defun @defun rlifacl formula @cindex factors (irreducible) @cindex irreducible factors @cindex irreducible factors list @cindex list of irreducible factors @cindex set of irreducible factors @cindex factorization List of irreducible factors. Returns the set of all irreducible factors of the nonzero terms occurring in @var{formula}. @smallexample rlifacl(x**2-1=0); @result{} @{x + 1,x - 1@} @end smallexample @end defun @defun rlifacml formula @cindex factors (irreducible) @cindex irreducible factors @cindex irreducible factors multiplicity list @cindex multiplicity list of irreducible factors @cindex factorization @rtindex multiplicity_list Multiplicity list of irreducible factors. Returns the set of all irreducible factors of the nonzero terms occurring in @var{formula} in a @var{multiplicity_list}. @end defun @defun rlterml formula @cindex term list @cindex list of terms List of terms. Returns the set of all nonzero terms occurring in @var{formula}. @end defun @defun rltermml formula @cindex term multiplicity list @cindex multiplicity list of terms @rtindex multiplicity_list Multiplicity list of terms. Returns the set of all nonzero terms occurring in @var{formula} in a @var{multiplicity_list}. @end defun @defun rlvarl formula @cindex list(s) of variables @cindex variable list(s) @cindex set of variables Variable lists. Returns both the list of variables occurring freely @cindex free variables and that of the variables occurring boundly @cindex bound variables in @var{formula} in a two-element list. Notice that the two member lists are not necessarily disjoint. @end defun @defun rlfvarl formula @cindex list(s) of variables @cindex variable list(s) @cindex free variables Free variable list. Returns the variables occurring freely in @var{formula} as a list. @end defun @defun rlbvarl formula @cindex list(s) of variables @cindex variable list(s) @cindex bound variables Bound variable list. Returns the variables occurring boundly in @var{formula} as a list. @end defun @defun rlstruct formula [@var{kernel}] @cindex formula structure @cindex structure of formula Structure of a formula. @var{kernel} is @code{v} by default. Returns a list @code{@{f,sl@}}. @code{f} is constructed from @var{formula} by replacing each occurrence of a term with a kernel constructed by concatenating a number to @var{kernel}. The @var{substitution_list} @rtindex substitution_list @code{sl} contains all substitutions @cindex substitution to obtain @var{formula} from @code{f}. @smallexample rlstruct(x*y=0 and (x=0 or y>0),v); @result{} @{v1 = 0 and (v2 = 0 or v3 > 0), @{v1 = x*y,v2 = x,v3 = y@}@} @end smallexample @end defun @defun rlifstruct formula [@var{kernel}] @cindex factors (irreducible) @cindex irreducible factors @cindex formula structure @cindex factorization Irreducible factor structure of a formula. @var{kernel} is @code{v} by default. Returns a list @code{@{f,sl@}}. @code{f} is constructed from @var{formula} by replacing each occurrence of an irreducible factor with a kernel constructed by adding a number to @var{kernel}. The returned @var{substitution_list} @rtindex substitution_list @code{sl} contains all substitutions @cindex substitution to obtain @var{formula} from @code{f}. @smallexample rlstruct(x*y=0 and (x=0 or y>0),v); @result{} @{v1*v2 = 0 and (v1 = 0 or v2 > 0), @{v1 = x,v2 = y@}@} @end smallexample @end defun @defun rlmatrix formula @cindex matrix of a formula @cindex remove quantifiers Matrix computation. Drops all @emph{leading} quantifiers @cindex quantifier from @var{formula}. @end defun @node Simplification @chapter Simplification @cindex simplification The goal of simplifying a first-order formula is to obtain an equivalent formula over the same language that is somehow simpler. @sc{redlog} knows three kinds of simplifiers that focus mainly on reducing the size of the given formula: The standard simplifier, tableau simplifiers, and Groebner simplifiers. The @sc{ofsf} @cindex @sc{ofsf} versions of these are described in @iftex [DS97]. @end iftex @ifinfo @ref{References,[DS97]}. @end ifinfo The @sc{acfsf} @cindex @sc{acfsf} versions are the same as the @sc{ofsf} @cindex @sc{ofsf} versions except for techniques that are particular to ordered fields such as treatment of square sums in connection with ordering relations. For @sc{dvfsf} @cindex @sc{dvfsf} there is no Groebner simplifier available. The parts of the standard simplifier that are particular to valued fields are described in @iftex [DS99]. @end iftex @ifinfo @ref{References,[DS99]}. @end ifinfo The tableau simplification is straightforwardly derived from the @emph{smart simplifications} described there. @menu * Standard Simplifier:: Fast and idempotent * Tableau Simplifier:: Coping with often occurring terms * Groebner Simplifier:: Detecting algebraic dependencies @end menu Besides reducing the size of formulas, it is a reasonable simplification goal, to reduce the degree of the quantified variables. Our method of decreasing the degree of quantified variables is described for @sc{ofsf} @cindex @sc{ofsf} in @ifinfo @ref{References,[DSW98]}. @end ifinfo @iftex [DSW98]. @end iftex A suitable variant is available also in @sc{acfsf} @cindex @sc{acfsf} but not in @sc{dvfsf}. @cindex @sc{dvfsf} @menu * Degree Decreaser:: @end menu @node Standard Simplifier @section Standard Simplifier The @dfn{Standard Simplifier} is a fast simplification algorithm that is frequently called internally by other @sc{redlog} algorithms. It can be applied automatically at the expression evaluation stage by turning on the switch @code{rlsimpl} @rvindex rlsimpl (@pxref{Global Switches,switch rlsimpl}). @deftp {Data Structure} theory A list of atomic formulas assumed to hold. @end deftp @defun rlsimpl formula [@var{theory}] @cindex simplification @cindex standard simplifier @rtindex theory Simplify. @var{formula} is simplified recursively such that the result is equivalent under the assumption that @var{theory} holds. Default for @var{theory} is the empty theory @code{@{@}}. Theory inconsistency may but need not be detected by @code{rlsimpl}. If @var{theory} is detected to be inconsistent, a corresponding error is raised. Note that under an inconsistent theory, @emph{any} formula is equivalent to the input, i.e., the result is meaningless. @var{theory} should thus be chosen carefully. @end defun @menu * General Features of the Standard Simplifier:: * General Standard Simplifier Switches:: * OFSF-specific Simplifications:: * OFSF-specific Standard Simplifier Switches:: * ACFSF-specific Simplifications:: * ACFSF-specific Standard Simplifier Switches:: * DVFSF-specific Simplifications:: * DVFSF-specific Standard Simplifier Switches:: * PASF-specific Simplifications:: * PASF-specific Standard Simplifier Switches:: @end menu @node General Features of the Standard Simplifier @subsection General Features of the Standard Simplifier The standard simplifier @code{rlsimpl} includes the following features common to all contexts: @itemize @bullet @item Replacement of atomic subformulas by simpler equivalents. These equivalents are not necessarily atomic (switches @code{rlsiexpl}, @code{rlsiexpla}, @rvindex rlsiexpla @rvindex rlsiexpl @pxref{General Standard Simplifier Switches}). For details on the simplification on the atomic formula level, see @ref{OFSF-specific Simplifications}, @ref{ACFSF-specific Simplifications}, and @ref{DVFSF-specific Simplifications}. @item Proper treatment of truth values. @cindex truth value @item Flattening @cindex flatten nested operators @cindex involutive @code{not} nested n-ary operator levels and resolving involutive applications of @code{not}. @rfindex not @item Dropping @code{not} @rfindex not operator with atomic formula arguments by changing the relation of the atomic formula appropriately. The languages of all contexts allow to do so. @item Changing @code{repl} @rfindex repl to @code{impl}. @rfindex impl @item Producing a canonical ordering @cindex canonical ordering among the atomic formulas on a given level (switch @code{rlsisort}, @rvindex rlsisort @pxref{General Standard Simplifier Switches}). @item Recognizing equal subformulas @cindex equal subformulas on a given level (switch @code{rlsichk}, @rvindex rlsichk @pxref{General Standard Simplifier Switches}). @item Passing down information that is collected during recursion (switches @code{rlsism}, @rvindex rlsism @code{rlsiidem}, @rvindex rlsiidem @pxref{General Standard Simplifier Switches}). The technique of @dfn{implicit theories} @cindex implicit theory @cindex theory (implicit) used for this is described in detail in @iftex [DS97] @end iftex @ifinfo @ref{References,[DS97]}, @end ifinfo for @sc{ofsf}/@sc{acfsf}, @cindex @sc{ofsf} @cindex @sc{acfsf} and in @iftex [DS99] @end iftex @ifinfo @ref{References,[DS99]}, @end ifinfo for @sc{dvfsf}. @cindex @sc{dvfsf} @item Considering interaction of atomic formulas on the same level and interaction with information inherited from higher levels (switch @code{rlsism}, @rvindex rlsism @pxref{General Standard Simplifier Switches}). The @dfn{smart simplification} @cindex smart simplification techniques used for this are beyond the scope of this manual. They are described in detail in @iftex [DS97] @end iftex @ifinfo @ref{References,[DS97]}, @end ifinfo for @sc{ofsf}/@sc{acfsf}, @cindex @sc{ofsf} @cindex @sc{acfsf} and in @iftex [DS99] @end iftex @ifinfo @ref{References,[DS99]}, @end ifinfo for @sc{dvfsf}. @cindex @sc{dvfsf} @end itemize @node General Standard Simplifier Switches @subsection General Standard Simplifier Switches @defvr Switch rlsiexpla @cindex explode terms @cindex simplification @cindex split atomic formula @cindex additively split atomic formula @cindex multiplicatively split atomic formula Simplify explode always. By default this switch is on. It is relevant with simplifications that allow to split one atomic formula into several simpler ones. Consider, e.g., the following simplification toggled by the switch @code{rlsipd} @rvindex rlsipd (@pxref{OFSF-specific Standard Simplifier Switches}). With @code{rlsiexpla} @rvindex rlsiexpla on, we obtain: @smallexample f := (a - 1)**3 * (a + 1)**4 >=0; 7 6 5 4 3 2 @result{} a + a - 3*a - 3*a + 3*a + 3*a - a - 1 >= 0 rlsimpl f; @rfindex rlsimpl @result{} a - 1 >= 0 or a + 1 = 0 @end smallexample With @code{rlsiexpla} off, @code{f} will simplify as in the description of the switch @code{rlsipd}. @code{rlsiexpla} is not used in the @sc{dvfsf} @cindex @sc{dvfsf} context. The @sc{dvfsf} simplifier behaves like @code{rlsiexpla} on. @end defvr @defvr Switch rlsiexpl @cindex simplification @cindex explode terms @cindex split atomic formula @cindex additively split atomic formula @cindex multiplicatively split atomic formula Simplify explode. By default this switch is on. Its role is very similar to that of @code{rlsiexpla}, @rvindex rlsiexpla but it considers the operator the scope of which the atomic formula occurs in: With @code{rlsiexpl} on @smallexample 7 6 5 4 3 2 a + a - 3*a - 3*a + 3*a + 3*a - a - 1 >= 0 @end smallexample simplifies as in the description of the switch @code{rlsiexpla} whenever it occurs in a disjunction, and it simplifies as in the description of the switch @code{rlsipd} @rvindex rlsipd (@pxref{OFSF-specific Standard Simplifier Switches}) else. @code{rlsiexpl} is not used in the @sc{dvfsf} @cindex @sc{dvfsf} context. The @sc{dvfsf} simplifier behaves like @code{rlsiexpla} on. @end defvr The user is not supposed to alter the settings of the following @emph{fix switches} (@pxref{Conventions}): @defvr {Fix Switch} rlsism @cindex simplification @cindex smart simplification Simplify smart. By default this switch is on. See the description of the function @code{rlsimpl} @rfindex rlsimpl (@pxref{Standard Simplifier}) for its effects. @smallexample rlsimpl(x>0 and x+1<0); @result{} false @end smallexample @end defvr @defvr {Fix Switch} rlsichk @cindex simplification @cindex multiple occurrences @cindex equal subformulas Simplify check. By default this switch is on enabling checking for equal sibling subformulas: @smallexample rlsimpl((x>0 and x-1<0) or (x>0 and x-1<0)); @result{} (x>0 and x-1<0) @rfindex rlsimpl @end smallexample @end defvr @defvr {Fix Switch} rlsiidem @cindex simplification @cindex idempotent simplification Simplify idempotent. By default this switch is on. It is relevant only with switch @code{rlsism} @rvindex rlsism on. Its effect is that @code{rlsimpl} @rfindex rlsimpl (@pxref{Standard Simplifier}) is idempotent in the very most cases, i.e., an application of @code{rlsimpl} to an already simplified formula yields the formula itself. @end defvr @defvr {Fix Switch} rlsiso @cindex simplification @cindex sort atomic formulas Simplify sort. By default this switch is on. It toggles the sorting of the atomic formulas on the single levels. @smallexample rlsimpl((a=0 and b=0) or (b=0 and a=0)); @rfindex rlsimpl @result{} a = 0 and b = 0 @end smallexample @end defvr @node OFSF-specific Simplifications @subsection OFSF-specific Simplifications @cindex simplification of atomic formulas @cindex atomic formula simplification In the @sc{ofsf} @cindex @sc{ofsf} context, the atomic formula simplification includes the following: @itemize @bullet @item Evaluation of variable-free atomic formulas to truth values. @cindex evaluate atomic formulas @cindex variable-free atomic formula @cindex truth value @item Make the left hand sides primitive over the integers @cindex primitive over the integers with positive head coefficient. @cindex positive head coefficient @item Evaluation of trivial square sums @cindex trivial square sum to truth values (switch @code{rlsisqf}, @rvindex rlsisqf @pxref{OFSF-specific Standard Simplifier Switches}). Additive splitting of trivial square sums (switch @code{rlsitsqspl}, @rvindex rlsitsqspl @pxref{OFSF-specific Standard Simplifier Switches}). @item In ordering inequalities, @cindex ordering inequality @cindex ordering constraint perform parity decomposition @cindex parity decomposition (similar to squarefree decomposition) of terms (switch @code{rlsipd}, @rvindex rlsipd @pxref{OFSF-specific Standard Simplifier Switches}) with the option to split an atomic formula @cindex split atomic formula @cindex multiplicatively split atomic formula multiplicatively into two simpler ones (switches @code{rlsiexpl} and @code{rlsiexpla}, @rvindex rlsiexpl @rvindex rlsiexpla @pxref{General Standard Simplifier Switches}). @item In equations and non-ordering inequalities, @cindex non-ordering inequalities replace left hand sides by their squarefree parts @cindex squarefree part (switch @code{rlsiatdv}, @rvindex rlsiatdv @pxref{OFSF-specific Standard Simplifier Switches}). Optionally, perform factorization @cindex factorization of equations and inequalities (switch @code{rlsifac}, @rvindex rlsifac @pxref{OFSF-specific Standard Simplifier Switches}, switches @code{rlsiexpl} and @code{rlsiexpla}, @pxref{General Standard Simplifier Switches}). @end itemize For further details on the simplification in ordered fields see the article @iftex [DS97]. @end iftex @ifinfo @ref{References,[DS97]}. @end ifinfo @node OFSF-specific Standard Simplifier Switches @subsection OFSF-specific Standard Simplifier Switches @defvr Switch rlsipw @cindex simplification @cindex prefer weak orderings @cindex weak orderings Simplification prefer weak orderings. Prefers weak orderings in contrast to strict orderings @cindex strict orderings with implicit theory @cindex implicit theory simplification. @code{rlsipw} is off by default, which leads to the following behavior: @smallexample rlsimpl(a<>0 and (a>=0 or b=0)); @result{} a <> 0 and (a > 0 or b = 0) @end smallexample This meets the simplification goal of small satisfaction sets for the atomic formulas. Turning on @code{rlsipw} will instead yield the following: @smallexample rlsimpl(a<>0 and (a>0 or b=0)); @result{} a <> 0 and (a >= 0 or b = 0) @end smallexample @end defvr Here we meet the simplification goal of convenient relations @cindex convenient relations when strict orderings are considered inconvenient. @defvr Switch rlsipo @cindex simplification @cindex prefer orderings Simplification prefer orderings. Prefers orderings in contrast to inequalities with implicit theory @cindex implicit theory simplification. @code{rlsipo} is on by default, which leads to the following behavior: @smallexample rlsimpl(a>=0 and (a<>0 or b=0)); @rfindex rlsimpl @result{} a >= 0 and (a > 0 or b = 0) @end smallexample This meets the simplification goal of small satisfaction sets @cindex small satisfaction sets for the atomic formulas. Turning it on leads, e.g., to the following behavior: @smallexample rlsimpl(a>=0 and (a>0 or b=0)); @rfindex rlsimpl @result{} a >= 0 and (a <> 0 or b = 0) @end smallexample Here, we meet the simplification goal of convenient relations @cindex convenient relations when orderings are considered inconvenient. @end defvr @defvr Switch rlsiatadv @cindex simplification of atomic formulas @cindex atomic formula simplification @cindex advanced atomic formula simplification Simplify atomic formulas advanced. By default this switch is on. Enables sophisticated atomic formula simplifications based on squarefree part @cindex squarefree part computations and recognition of trivial square sums. @cindex trivial square sum @smallexample rlsimpl(a**2 + 2*a*b + b**2 <> 0); @rfindex rlsimpl @result{} a+b <> 0 rlsimpl(a**2 + b**2 + 1 > 0); @result{} true @end smallexample Furthermore, splitting of trivial square sums @cindex split trivial square sum (switch @code{rlsitsqspl}), @rvindex rlsitsqspl parity decompositions @cindex parity decomposition (switch @code{rlsipd}), @rvindex rlsipd and factorization @cindex factorization of equations and inequalities (switch @code{rlsifac}) @rvindex rlsifac are enabled. @end defvr @defvr Switch rlsitsqspl @cindex trivial square sum @cindex split trivial square sum @cindex split atomic formula @cindex additively split atomic formula Simplify split trivial square sum. This is on by default. It is ignored with @code{rlsiadv} @rvindex rlsiadv off. Trivial square sums are split additively depending on @code{rlsiexpl} and @code{rlsiexpla} @rvindex rlsiexpl @rvindex rlsiexpla (@pxref{General Standard Simplifier Switches}): @smallexample rlsimpl(a**2+b**2>0); @rfindex rlsimpl @result{} a <> 0 or b <> 0 @end smallexample @end defvr @defvr Switch rlsipd @cindex simplification @cindex parity decomposition Simplify parity decomposition. By default this switch is on. It is ignored with @code{rlsiatadv} @rvindex rlsiatadv off. @code{rlsipd} toggles the parity decomposition of terms occurring with ordering relations. @cindex ordering relations @smallexample f := (a - 1)**3 * (a + 1)**4 >= 0; 7 6 5 4 3 2 @result{} a + a - 3*a - 3*a + 3*a + 3*a - a - 1 >= 0 rlsimpl f; @rfindex rlsimpl @group 3 2 @result{} a + a - a - 1 >= 0 @end group @end smallexample The atomic formula is possibly split into two parts according to the setting of the switches @code{rlsiexpl} and @code{rlsiexpla} @rvindex rlsiexpl @rvindex rlsiexpla (@pxref{General Standard Simplifier Switches}). @end defvr @defvr Switch rlsifac @cindex simplification @cindex factorization Simplify factorization. By default this switch is on. It is ignored with @code{rlsiatadv} @rvindex rlsiatadv off. Splits @cindex split atomic formula @cindex multiplicatively split atomic formula equations and inequalities via factorization of their left hand side terms into a disjunction or a conjunction, respectively. This is done in dependence on @code{rlsiexpl} and @code{rlsiexpla} @rvindex rlsiexpl @rvindex rlsiexpla (@pxref{General Standard Simplifier Switches}). @end defvr @node ACFSF-specific Simplifications @subsection ACFSF-specific Simplifications @cindex simplification of atomic formulas @cindex atomic formula simplification In the @sc{acfsf} @cindex @sc{acfsf} case the atomic formula simplification includes the following: @itemize @bullet @item Evaluation of variable-free atomic formulas to truth values. @cindex evaluate atomic formulas @cindex variable-free atomic formula @cindex truth value @item Make the left hand sides primitive over the integers @cindex primitive over the integers with positive head coefficient. @cindex positive head coefficient @item Replace left hand sides of atomic formulas by their squarefree parts @cindex squarefree part (switch @code{rlsiatdv}, @rvindex rlsiatdv @pxref{OFSF-specific Standard Simplifier Switches}). Optionally, perform factorization @cindex factorization of equations and inequalities (switch @code{rlsifac}, @rvindex rlsifac @pxref{OFSF-specific Standard Simplifier Switches}, switches @code{rlsiexpl} @rvindex rlsiexpl and @code{rlsiexpla}, @rvindex rlsiexpla @pxref{General Standard Simplifier Switches}). @end itemize For details see the description of the simplification for ordered fields in @iftex [DS97]. @end iftex @ifinfo @ref{References,[DS97]}. @end ifinfo This can be easily adapted to algebraically closed fields. @node ACFSF-specific Standard Simplifier Switches @subsection ACFSF-specific Standard Simplifier Switches The switches @code{rlsiatadv} @rvindex rlsiatadv and @code{rlsifac} @rvindex rlsifac have the same effects as in the @sc{ofsf} @cindex @sc{ofsf} context (@pxref{OFSF-specific Standard Simplifier Switches}). @node DVFSF-specific Simplifications @subsection DVFSF-specific Simplifications @cindex simplification of atomic formulas @cindex atomic formula simplification In the @sc{dvfsf} @cindex @sc{dvfsf} case the atomic formula simplification includes the following: @itemize @bullet @item Evaluation of variable-free atomic formulas to truth values provided that p is known. @cindex evaluate atomic formulas @cindex variable-free atomic formula @cindex truth value @item Equations and inequalities can be treated as in @sc{acfsf} @cindex @sc{acfsf} (@pxref{ACFSF-specific Simplifications}). Moreover powers of p @cindex power of p @cindex cancel powers of p can be cancelled. @item With valuation relations, @cindex valuation relation the @sc{gcd} @cindex @sc{gcd} @cindex greatest common divisor @cindex cancel @sc{gcd} of both sides is cancelled and added appropriately as an equation or inequality. @item Valuation relations @cindex valuation relation involving zero sides can be evaluated or at least turned into equations or inequalities. @item For concrete p, integer coefficients with valuation relations can be replaced by a power of p @cindex power of p on one side of the relation. @item For unspecified p, polynomials in p can often be replaced by one monomial. @item For unspecified p, valuation relations containing a monomial in p on one side, and an integer on the other side can be transformed into @code{z ~ 1} or @code{z /~ 1}, where @code{z} is an integer. @end itemize For details on simplification in p-adic fields see the article @iftex [DS99]. @end iftex @ifinfo @ref{References,[DS99]}. @end ifinfo Atomic formulas of the form @code{z ~ 1} or @code{z /~ 1}, where @code{z} is an integer, can be split @cindex split atomic formula @cindex multiplicatively split atomic formula into several ones via integer factorization. @cindex integer factorization @cindex factorization This simplification is often reasonable on final results. It explicitly discovers those primes p for which the formula holds. There is a special function for this simplification: @defun rlexplats formula @cindex explode atomic formulas @cindex split atomic formula @cindex multiplicatively split atomic formula Explode atomic formulas. Factorize @cindex integer factorization @cindex factorization atomic formulas of the form @code{z ~ 1} or @code{z /~ 1}, where @code{z} is an integer. @code{rlexplats} obeys the switches @code{rlsiexpla} @rvindex rlsiexpla and @code{rlsiexpl} @rvindex rlsiexpl (@pxref{General Standard Simplifier Switches}), but not @code{rlsifac} @rvindex rlsifac (@pxref{DVFSF-specific Standard Simplifier Switches}). @end defun @node DVFSF-specific Standard Simplifier Switches @subsection DVFSF-specific Standard Simplifier Switches The context @sc{dvfsf} @cindex @sc{dvfsf} knows no special simplifier switches, and ignores the general switches @code{rlsiexpla} @rvindex rlsiexpla and @code{rlsiexpl} @rvindex rlsiexpl (@pxref{General Standard Simplifier Switches}). It behaves like @code{rlsiexpla} on. The simplifier contains numerous sophisticated simplifications for atomic formulas in the style of @code{rlsiatadv} @rvindex rlsiatadv on (@pxref{OFSF-specific Standard Simplifier Switches}). @defvr Switch rlsifac @cindex simplification @cindex factorization @cindex integer factorization Simplify factorization. By default this switch is on. Toggles certain simplifications that require @emph{integer} factorization. @xref{DVFSF-specific Simplifications}, for details. @end defvr @node PASF-specific Simplifications @subsection PASF-specific Simplifications The main PASF-specific simplification feature is the content elimination in atomic formulas. @smallexample f := 3 * x + 6 * y - 9 = 0 rlsimpl f; @rfindex rlsimpl @group @result{} x + 2 * y - 3 = 0 @end group f := 3 * x + 6 * y - 7 < 0 rlsimpl f; @rfindex rlsimpl @group @result{} x + 2 * y - 2 <= 0 @end group f := cong(3 * x + 6 * y - 3, 0, 9); rlsimpl f; @rfindex rlsimpl @group @result{} x + 2 * y - 1 =~ 0 (3) @end group @end smallexample Futhermore evaluation of domain valued atomic formulas is performed. @smallexample f := 3 = 0 rlsimpl f; @rfindex rlsimpl @group @result{} false @end group f := cong(y+x+z,0,1); rlsimpl f; @rfindex rlsimpl @group @result{} true @end group @end smallexample @node PASF-specific Standard Simplifier Switches @subsection PASF-specific Standard Simplifier Switches @defun rlpasfsimplify formula Simplifies the output formula after the elimination of each quantifier. By default this switch is on. @end defun @defun rlpasfexpand formula Expands the output formula (with range predicates) after the elimination of each quantifier. This switch is by default off due to immense overhead of the range predicate expantion. @end defun @defun rlsiatadv formula Turns the advanced PASF-speciefic simplification of atomic formulas on. See @xref{PASF-specific Simplifications} for details. @end defun @node Tableau Simplifier @section Tableau Simplifier Although our standard simplifier (@pxref{Standard Simplifier}) already combines information located on different boolean levels, it preserves the basic boolean structure of the formula. The tableau methods, in contrast, provide a technique for changing the boolean structure @cindex change boolean structure of a formula by constructing case distinctions. @cindex case distinction Compared to the standard simplifier they are much slower. For details on tableau simplification see @ifinfo @ref{References,[DS97]}. @end ifinfo @iftex [DS97]. @end iftex @deftp {Data Structure} {cdl} Case distinction list. @cindex case distinction This is a list of atomic formulas considered as a disjunction. @end deftp @defun rltab formula cdl @cindex simplification @cindex tableau @rtindex cdl Tableau method. The result is a tableau wrt.@: @var{cdl}, i.e., a simplified equivalent of the disjunction over the specializations wrt.@: all atomic formulas in @var{cdl}. @smallexample rltab((a = 0 and (b = 0 or (d = 0 and e = 0))) or (a = 0 and c = 0),@{a=0,a<>0@}); @result{} (a = 0 and (b = 0 or c = 0 or (d = 0 and e = 0))) @end smallexample @end defun @defun rlatab formula @cindex simplification @cindex tableau @cindex automatic tableau Automatic tableau method. Tableau steps wrt.@: a case distinction over the signs of all terms occurring in @var{formula} are computed and the best result, i.e., the result with the minimal number of atomic formulas is returned. @end defun @defun rlitab formula @cindex simplification @cindex tableau @cindex iterative tableau Iterative automatic tableau method. @var{formula} is simplified by iterative applications of @code{rlatab}. @rfindex rlatab The exact procedure depends on the switch @code{rltabib}. @rvindex rltabib @end defun @defvr Switch rltabib @cindex simplification @cindex tableau @cindex branch-wise tableau iteration Tableau iterate branch-wise. By default this switch is on. It controls the procedure @code{rlitab}. @rfindex rlitab If @code{rltabib} is off, @code{rlatab} @rfindex rlatab is iteratively applied to the argument formula as long as shorter results can be obtained. In case @code{rltabib} is on, the corresponding next tableau step is not applied to the last tableau result but independently to each single branch. The iteration stops when the obtained formula is not smaller than the corresponding input. @end defvr @node Groebner Simplifier @section Groebner Simplifier @cindex Groebner simplifier The Groebner simplifier is not available in the @sc{dvfsf} @cindex @sc{dvfsf} context. It considers order theoretical and algebraic simplification @cindex algebraic simplification rules between the atomic formulas of the input formula. Currently the Groebner simplifier is not idempotent. The name is derived from the main mathematical tool used for simplification: Computing Groebner bases @cindex Groebner basis of certain subsets of terms occurring in the atomic formulas. For calling the Groebner simplifier there are the following functions: @defun rlgsc formula [@var{theory}] @defunx rlgsd formula [@var{theory}] @defunx rlgsn formula [@var{theory}] @rtindex theory @cindex normal form @cindex boolean normal form @cindex simplification @cindex Groebner simplifier @cindex polynomial reduction @cindex reduce polynomials Groebner simplifier. @var{formula} is a quantifier-free formula. Default for @var{theory} is the empty theory @code{@{@}}. The functions differ in the boolean normal form that is computed at the beginning. @code{rlgsc} computes a conjunctive normal form, @cindex conjunctive normal form @cindex @sc{cnf} @code{rlgsd} computes a disjunctive normal form, @cindex disjunctive normal form @cindex @sc{dnf} and @code{rlgsn} heuristically decides for either a conjunctive or a disjunctive normal form depending on the structure of @var{formula}. After computing the corresponding normal form, the formula is simplified using Groebner simplification techniques. The returned formula is equivalent to the input formula wrt.@: @var{theory}. @smallexample rlgsd(x=0 and ((y = 0 and x**2+2*y > 0) or (z=0 and x**3+z >= 0))); @result{} x = 0 and z = 0 @end smallexample @smallexample rlgsc(x neq 0 or ((y neq 0 or x**2+2*x*y <= 0) and (z neq 0 or x**3+z < 0))); @result{} x <> 0 or z <> 0 @end smallexample @end defun The heuristic used by @code{rlgsn} @rfindex rlgsn is intended to find the smaller boolean normal form @cindex boolean normal form among @sc{cnf} an @sc{dnf}. Note that, anyway, the simplification of the smaller normal form can lead to a larger final result than that of the larger one. The Groebner simplifiers use the Groebner package of @sc{reduce} to compute the various Groebner bases. By default, the @code{revgradlex} term order is used, and no optimizations of the order between the variables are applied. The other switches and variables of the Groebner package are not controlled by the Groebner simplifier. They can be adjusted by the user. In contrast to the standard simplifier @code{rlsimpl} @rfindex rlsimpl (@pxref{Standard Simplifier}), the Groebner simplifiers can in general produce formulas containing more atomic formulas than the input. This cannot happen if the switches @code{rlgsprod}, @rvindex rlgsprod @code{rlgsred}, @rvindex rlgsred and @code{rlgssub} @rvindex rlgssub are off and the input formula is a simplified boolean normal form. The functionality of the Groebner simplifiers @code{rlgsc}, @rfindex rlgsc @code{rlgsd}, @rfindex rlgsd and @code{rlgsn} @rfindex rlgsn is controlled by numerous switches. In most cases the default settings lead to a good simplification. @defvr Switch rlgsrad @cindex radical membership test @cindex ideal membership test Groebner simplifier radical membership test. By default this switch is on. If the switch is on the Groebner simplifier does not only use ideal membership tests for simplification but also radical membership tests. This leads to better simplifications but takes considerably more time. @end defvr @defvr Switch rlgssub @cindex substitution Groebner simplifier substitute. By default this switch is on. Certain subsets of atomic formulas are substituted by equivalent ones. Both the number of atomic formulas and the complexity of the terms @cindex complexity of terms may increase or decrease independently. @end defvr @defvr Switch rlgsbnf @cindex boolean normal form @cindex normal form Groebner simplifier boolean normal form. By default this switch is on. Then the simplification starts with a boolean normal form computation. If the switch is off, the simplifiers expect a boolean normal form as the argument @var{formula}. @end defvr @defvr Switch rlgsred @cindex polynomial reduction @cindex reduce polynomials @cindex complexity of terms Groebner simplifier reduce polynomials. By default this switch is on. It controls the reduction of the terms wrt.@: the computed Groebner bases. The number of atomic formulas is never increased. Mind that by reduction the terms can become more complicated. @end defvr @defvr {Advanced Switch} rlgsvb @cindex verbosity output @cindex protocol Groebner simplifier verbose. By default this switch is on. It toggles verbosity output of the Groebner simplifier. Verbosity output is given if and only if both @code{rlverbose} @rvindex rlverbose (@pxref{Global Switches}) and @code{rlgsvb} are on. @end defvr @defvr {Advanced Switch} rlgsprod Groebner simplifier product. By default this switch is off. If this switch is on then conjunctions of inequalities and disjunctions of equations are contracted @cindex unsplit atomic formulas @cindex contract atomic formulas multiplicatively to one atomic formula. This reduces the number of atomic formulas but in most cases it raises the complexity of the terms. Most simplifications recognized by considering products are detected also with @code{rlgsprod} off. @end defvr @defvr {Advanced Switch} rlgserf Groebner simplifier evaluate reduced form. @cindex evaluate reduced form By default this switch is on. It controls the evaluation of the atomic formulas @cindex evaluate atomic formulas to truth values. @cindex truth value If this switch is on, the standard simplifier (@pxref{Standard Simplifier}) @cindex standard simplifier is used to evaluate atomic formulas. Otherwise atomic formulas are evaluated only if their left hand side is a domain element. @end defvr @defvr {Advanced Switch} rlgsutord @cindex term order Groebner simplifier user defined term order. By default this switch is off. Then all Groebner basis computations and reductions @cindex polynomial reduction @cindex reduce polynomials are performed with respect to the @code{revgradlex} @cindex @code{revgradlex} term order. If this switch is on, the Groebner simplifier minds the term order selected with the @code{torder} @rfindex torder statement. For passing a variable list to @code{torder}, note that @code{rlgsradmemv!*} @vrindex rlgsradmemv!* is used as the tag variable for radical membership tests. @cindex radical membership test @end defvr @defvr {Fluid} rlgsradmemv!* @cindex radical membership test Radical membership test variable. This fluid contains the tag variable @cindex tag variable used for the radical membership test with switch @code{rlgsrad} @rvindex rlgsrad on. It can be used to pass the variable explicitly to @code{torder} @rfindex torder with switch @code{rlgsutord} @rvindex rlgsutord on. @end defvr @node Degree Decreaser @section Degree Decreaser @cindex degree @cindex degree restriction The quantifier elimination procedures of @sc{redlog} (@pxref{Quantifier Elimination}) obey certain degree restrictions on the bound variables. For this reason, there are degree-decreasing simplifiers available, which are automatically applied by the corresponding quantifier elimination procedures. There is no degree decreaser for the @sc{dvfsf} @cindex @sc{dvfsf} context available. @defun rldecdeg formula Decrease degrees. @cindex decrease degree Returns a formula equivalent to @var{formula}, hopefully decreasing the degrees of the bound variables. In the @sc{ofsf} @cindex @sc{ofsf} context there are in general some sign conditions @cindex sign conditions on the variables added, which slightly increases the number of contained atomic formulas. @smallexample rldecdeg ex(@{b,x@},m*x**4711+b**8>0); @result{} ex b (b >= 0 and ex x (b + m*x > 0)) @end smallexample @end defun @defun rldecdeg1 formula [@var{varlist}] @cindex decrease degree Decrease degrees subroutine. This provides a low-level entry point to the degree decreaser. The variables to be decreased are not determined by regarding quantifiers but are explicitly given by @var{varlist}, where the empty @var{varlist} selects @emph{all} free variables of @code{f}. The return value is a list @code{@{f,l@}}. @code{f} is a formula, and @code{l} is a list @code{@{...,@{v,d@},...@}}, where @code{v} is from @var{varlist} and @code{d} is an integer. @code{f} has been obtained from @var{formula} by substituting @cindex substitution @code{v} for @code{v**d}. The sign conditions necessary with the @sc{ofsf} @cindex @sc{ofsf} context are not generated automatically, but have to be constructed by hand for the variables @code{v} with even degree @code{d} in @code{l}. @smallexample rldecdeg1(m*x**4711+b**8>0,@{b,x@}); @result{} @{b + m*x > 0,@{@{x,4711@},@{b,8@}@}@} @end smallexample @end defun @node Normal Forms @chapter Normal Forms @menu * Boolean Normal Forms:: CNF and DNF * Miscellaneous Normal Forms:: Negation, prenex, anti-prenex @end menu @node Boolean Normal Forms @section Boolean Normal Forms For computing small boolean normal forms, @cindex boolean normal form see also the documentation of the procedures @code{rlgsc} @rfindex rlgsc and @code{rlgsd} @rfindex rlgsd (@ref{Groebner Simplifier}). @defun rlcnf formula @cindex normal form @cindex conjunctive normal form @cindex @sc{cnf} Conjunctive normal form. @var{formula} is a quantifier-free formula. Returns a conjunctive normal form of @var{formula}. @smallexample rlcnf(a = 0 and b = 0 or b = 0 and c = 0); @result{} (a = 0 or c = 0) and b = 0 @end smallexample @end defun @defun rldnf formula @cindex normal form @cindex disjunctive normal form @cindex @sc{dnf} Disjunctive normal form. @var{formula} is a quantifier-free formula. Returns a disjunctive normal form of @var{formula}. @smallexample rldnf((a = 0 or b = 0) and (b = 0 or c = 0)); @result{} (a = 0 and c = 0) or b = 0 @end smallexample @end defun @defvr Switch rlbnfsm @cindex boolean normal form @cindex smart @sc{bnf} computation @cindex simplifier recognized implication Boolean normal form smart. By default this switch is off. If on, @emph{simplifier recognized implication} @cindex simplifier recognized implication @ifinfo (@pxref{References,[DS97]}) @end ifinfo @iftex [DS97] @end iftex is applied by @code{rlcnf} @rfindex rlcnf and @code{rldnf}. @rfindex rldnf This leads to smaller normal forms but is considerably time consuming. @end defvr @defvr {Fix Switch} rlbnfsac @cindex boolean normal form @cindex subsumption @cindex cut Boolean normal forms subsumption and cut. By default this switch is on. With boolean normal form computation, subsumption and cut strategies are applied by @code{rlcnf} @rfindex rlcnf and @code{rldnf} @rfindex rldnf to decrease the number of clauses. @cindex decrease number of clauses We give an example: @smallexample rldnf(x=0 and y<0 or x=0 and y>0 or x=0 and y<>0 and z=0); @result{} (x = 0 and y <> 0) @end smallexample @end defvr @node Miscellaneous Normal Forms @section Miscellaneous Normal Forms @defun rlnnf formula @cindex normal form @cindex negation normal form @cindex @sc{nnf} Negation normal form. Returns a @dfn{negation normal form} of @var{formula}. This is an @code{and}-@code{or}-combination of atomic formulas. Note that in all contexts, we use languages @cindex language such that all negations can be encoded by relations (@pxref{Format and Handling of Formulas}). We give an example: @smallexample rlnnf(a = 0 equiv b > 0); @result{} (a = 0 and b > 0) or (a <> 0 and b <= 0) @end smallexample @code{rlnnf} accepts formulas containing quantifiers, but it does not eliminate quantifiers. @cindex quantifier @end defun @defun rlpnf formula @cindex normal form @cindex prenex normal form @cindex @sc{pnf} Prenex normal form. Returns a prenex normal form of @var{formula}. The number of quantifier changes @cindex quantifier changes in the result is minimal among all prenex normal forms that can be obtained from @var{formula} by only moving quantifiers to the outside. When @var{formula} contains two quantifiers with the same variable such as in @ifinfo @example ex x (x = 0) and ex x (x <> 0) @end example @end ifinfo @tex $$\exists x(x = 0) \land \exists x (x \neq 0)$$ @end tex there occurs a name conflict. It is resolved according to the following rules: @cindex rename variables @cindex variable renaming @itemize @bullet @item Every bound variable that stands in conflict with any other variable is renamed. @item Free variables are never renamed. @end itemize Hence @code{rlpnf} applied to the above example formula yields @smallexample rlpnf(ex(x,x=0) and ex(x,x<>0)); @result{} ex x0 ex x1 (x0 = 0 and x1 <> 0) @end smallexample @end defun @defun rlapnf formula @cindex anti-prenex normal form @cindex move quantifiers inside @cindex prenex normal form Anti-prenex normal form. Returns a formula equivalent to @var{formula} where all quantifiers are moved to the inside as far as possible. @cindex quantifier @cindex move quantifiers inside @smallexample rlapnf ex(x,all(y,x=0 or (y=0 and x=z))); @result{} ex x (x = 0) or (all y (y = 0) and ex x (x - z = 0)) @end smallexample @end defun @defun rltnf formula terml @cindex normal form @cindex term normal form Term normal form. @var{terml} is a list of terms. This combines @sc{dnf} @cindex @sc{dnf} @cindex disjunctive normal form computation with tableau @cindex tableau ideas (@pxref{Tableau Simplifier}). A typical choice for @var{terml} is @code{rlterml} @var{formula}. @rfindex rlterml If the switch @code{rltnft} @rvindex rltnft is off, then @code{rltnf(@var{formula},rlterml @var{formula})} returns a @sc{dnf}. @end defun @defvr Switch rltnft @cindex term normal form Term normal form tree variant. By default this switch is on causing @code{rltnf} to return a deeply nested formula. @cindex deeply nested formula @end defvr @node Quantifier Elimination and Variants @chapter Quantifier Elimination and Variants @cindex comprehensive Groebner Basis @cindex @sc{cgb} @emph{Quantifier elimination} computes quantifier-free equivalents @cindex quantifier-free equivalent for given first-order formulas. For @sc{ofsf} @cindex @sc{ofsf} there are two methods available: @enumerate @item Virtual substitution @cindex virtual substitution based on elimination set @cindex elimination set ideas @ifinfo @ref{References,[Wei88]}. @end ifinfo @iftex [Wei88]. @end iftex This implementation is restricted to at most quadratic occurrences of the quantified variables, but includes numerous heuristic strategies for coping with higher degrees. See @ifinfo @ref{References,[LW93]}, @ref{References,[Wei97]}, @end ifinfo @iftex [LW93], [Wei97] @end iftex for details of the method. @item Partial cylindrical algebraic decomposition @cindex cylindrical algebraic decomposition @cindex partial cylindrical algebraic decomposition (CAD) @cindex CAD introduced by Collins and Hong @ifinfo @ref{References,[CH91]}. @end ifinfo @iftex [CH91]. @end iftex There are no degree restrictions with CAD. @end enumerate For @sc{dvfsf} @cindex @sc{dvfsf} we use the virtual substitution method @cindex virtual substitution that is also available for @sc{ofsf}. @cindex @sc{ofsf} Here, the implementation is restricted to linear occurrences of the quantified variables. There are also heuristic strategies for coping with higher degrees included. The method is described in detail in @ifinfo @ref{References,[Stu00]}. @end ifinfo @iftex [Stu00]. @end iftex The @sc{acfsf} @cindex @sc{acfsf} quantifier elimination is based on @emph{comprehensive Groebner basis} @cindex comprehensive Groebner basis computation; there are no degree restrictions @cindex degree restriction for this context @ifinfo @ref{References,[Wei92]}. @end ifinfo @iftex [Wei92]. @end iftex @menu * Quantifier Elimination:: * Generic Quantifier Elimination:: * Local Quantifier Elimination:: * Linear Optimization:: @end menu @node Quantifier Elimination @section Quantifier Elimination @subsection Virtual Substitution @defun rlqe formula [@var{theory}] @rtindex theory @cindex quantifier elimination Quantifier elimination by virtual substitution. Returns a quantifier-free equivalent @cindex quantifier-free equivalent of @var{formula} (wrt.@: @var{theory}). In the contexts @sc{ofsf} @cindex @sc{ofsf} and @sc{dvfsf}, @cindex @sc{dvfsf} @var{formula} has to obey certain degree restrictions. @cindex degree restriction There are various techniques for decreasing the degree @cindex decrease degree of the input and of intermediate results built in. In case that not all variables can be eliminated, the resulting formula is not quantifier-free but still equivalent. @end defun For degree decreasing @cindex decrease degree heuristics see, e.g., @ref{Degree Decreaser}, or the switches @code{rlqeqsc}/@code{rlqesqsc}. @rvindex rlqeqsc @rvindex rlqesqsc @deftp {Data Structure} {elimination_answer} A list of @dfn{condition--solution pairs}, @cindex condition--solution pairs i.e., a list of pairs consisting of a quantifier-free formula and a set of equations. @end deftp @defun rlqea formula [@var{theory}] @rtindex theory @cindex quantifier elimination @cindex solution points @cindex extended quantifier elimination @cindex answer @cindex sample solution @rtindex elimination_answer Quantifier elimination with answer. Returns an @ifinfo @var{elimination_answer} @end ifinfo @iftex @var{elim@-i@-na@-tion_an@-swer} @end iftex obtained the following way: @var{formula} is wlog.@: prenex. All quantifier blocks but the outermost one are eliminated. For this outermost block, the constructive information obtained by the elimination is saved: @itemize @bullet @item In case the considered block is existential, for each evaluation of the free variables we know the following: Whenever a @dfn{condition} holds, then @var{formula} is @code{true} @rvindex true under the given evaluation, and the @dfn{solution} @cindex solution is @emph{one} possible evaluation for the outer block variables satisfying the matrix. @item The universally quantified case is dual: Whenever a @dfn{condition} is false, then @var{formula} is @code{false}, @rvindex false and the @dfn{solution} is @emph{one} possible counterexample. @cindex counterexample @end itemize As an example we show how to find conditions and solutions for a system of two linear constraints: @smallexample rlqea ex(x,x+b1>=0 and a2*x+b2<=0); 2 - b2 @result{} @{@{a2 *b1 - a2*b2 >= 0 and a2 <> 0,@{x = -------@}@}, a2 @{a2 < 0 or (a2 = 0 and b2 <= 0),@{x = infinity1@}@}@} @end smallexample The answer can contain constants named @code{infinity} @cindex @code{infinity} or @code{epsilon}, @cindex @code{epsilon} both indexed by a number: All @code{infinity}'s are positive and infinite, and all @code{epsilon}'s are positive and infinitesimal wrt.@: the considered field. Nothing is known about the ordering among the @code{infinity}'s and @code{epsilon}'s though this can be relevant for the points to be solutions. With the switch @code{rounded} @rvindex rounded on, the @code{epsilon}'s are evaluated to zero. @code{rlqea} is not available in the context @sc{acfsf}. @cindex @sc{acfsf} @end defun @defvr {Switch} rlqeqsc @defvrx Switch rlqesqsc @cindex quantifier elimination @cindex quadratic special case @cindex super quadratic special case Quantifier elimination (super) quadratic special case. By default these switches are off. They are relevant only in @sc{ofsf}. @cindex @sc{ofsf} If turned on, alternative elimination sets are used for certain special cases by @code{rlqe}/@code{rlqea} @rfindex rlqe @rfindex rlqea and @code{rlgqe}/@code{rlgqea}. @rfindex rlgqe @rfindex rlgqea (@pxref{Generic Quantifier Elimination}). They will possibly avoid violations of the degree restrictions, @cindex degree restriction but lead to larger results in general. Former versions of @sc{redlog} without these switches behaved as if @code{rlqeqsc} was on and @code{rlqesqsc} was off. @end defvr @defvr {Advanced Switch} rlqedfs @cindex quantifier elimination @cindex depth first search @cindex breadth first search Quantifier elimination depth first search. By default this switch is off. It is also ignored in the @sc{acfsf} @cindex @sc{acfsf} context. It is ignored with the switch @code{rlqeheu} @rvindex rlqeheu on, which is the default for @sc{ofsf}. @cindex @sc{ofsf} Turning @code{rlqedfs} on makes @code{rlqe}/@code{rlqea} @rfindex rlqe @rfindex rlqea and @code{rlgqe}/@code{rlgqea} @rfindex rlgqe @rfindex rlgqea (@pxref{Generic Quantifier Elimination}) work in a depth first search manner instead of breadth first search. This saves space, @cindex save space and with decision problems, @cindex decision problem where variable-free atomic formulas can be evaluated @cindex evaluate atomic formulas to truth values, @cindex truth value it might save time. @cindex save time In general, it leads to larger results. @end defvr @defvr {Advanced Switch} rlqeheu @cindex heuristic @cindex search heuristic @cindex quantifier elimination @cindex depth first search @cindex breadth first search Quantifier elimination search heuristic. By default this switch is on in @sc{ofsf} @cindex @sc{ofsf} and off in @sc{dvfsf}. @cindex @sc{dvfsf} It is ignored in @sc{acfsf}. @cindex @sc{acfsf} Turning @code{rlqeheu} on causes the switch @code{rlqedfs} @rvindex rlqedfs to be ignored. @code{rlqe}/@code{rlqea} @rfindex rlqe @rfindex rlqea and @code{rlgqe}/@code{rlgqea} @rfindex rlgqe @rfindex rlgqea (@pxref{Generic Quantifier Elimination}) will then decide between breadth first search and depth first search for each quantifier block, @cindex quantifier block where @sc{dfs} is chosen when the problem is a decision problem. @cindex decision problem @end defvr @defvr {Advanced Switch} rlqepnf @cindex quantifier elimination @cindex prenex normal form Quantifier elimination compute prenex normal form. By default this switch is on, which causes that @code{rlpnf} @rfindex rlpnf (@pxref{Miscellaneous Normal Forms}) is applied to @var{formula} before starting the elimination process. If the argument formula to @code{rlqe}/@code{rlqea} @rfindex rlqe @rfindex rlqea or @code{rlgqe}/@code{rlgqea} @rfindex rlgqe @rfindex rlgqea (@pxref{Generic Quantifier Elimination}) is already prenex, this switch can be turned off. This may be useful with formulas containing @code{equiv} @rfindex equiv since @code{rlpnf} applies @code{rlnnf}, @rfindex rlnnf (@pxref{Miscellaneous Normal Forms}), and resolving equivalences can double the size of a formula. @code{rlqepnf} is ignored in @sc{acfsf}, @cindex @sc{acfsf} since @sc{nnf} is necessary for elimination there. @end defvr @defvr {Fix Switch} rlqesr @cindex separate roots Quantifier elimination separate roots. This is off by default. It is relevant only in @sc{ofsf} @cindex @sc{ofsf} for @code{rlqe}/@code{rlgqe} @rfindex rlqe @rfindex rlqea and for all but the outermost quantifier block in @code{rlqea}/@code{rlgqea}. @rfindex rlgqe @rfindex rlgqea For @code{rlqea} and @code{rlgqea} see @ref{Generic Quantifier Elimination}. It affects the technique for substituting @cindex substitution the two solutions of a quadratic constraint @cindex quadratic constraint during elimination. @end defvr The following two functions @code{rlqeipo} @rfindex rlqeipo and @code{rlqews} @rfindex rlqews are experimental implementations. The idea there is to overcome the obvious disadvantages of prenex normal forms with elimination set methods. In most cases, however, the classical method @code{rlqe} @rfindex rlqe has turned out superior. @defun rlqeipo formula [@var{theory}] @rtindex theory @cindex quantifier elimination @cindex prenex normal form @cindex anti-prenex normal form Quantifier elimination by virtual substitution in position. Returns a quantifier-free equivalent @cindex quantifier-free equivalent to @var{formula} by iteratively making @var{formula} anti-prenex (@pxref{Miscellaneous Normal Forms}) and eliminating one quantifier. @end defun @defun rlqews formula [@var{theory}] @rtindex theory @cindex quantifier elimination @cindex prenex normal form @cindex anti-prenex normal form Quantifier elimination by virtual substitution with selection. @var{formula} has to be prenex, if the switch @code{rlqepnf} @rvindex rlqepnf is off. Returns a quantifier-free equivalent @cindex quantifier-free equivalent to @var{formula} by iteratively selecting a quantifier from the innermost block, moving it inside as far as possible, and then eliminating it. @code{rlqews} is not available in @sc{acfsf}. @cindex @sc{acfsf} @end defun @subsection Cylindrical Algebraic Decomposition @cindex cylindrical algebraic decomposition @defun rlcad formula @cindex quantifier elimination @cindex cylindrical algebraic decomposition Cylindrical algebraic decomposition. Returns a quantifier-free equivalent of @var{formula}. Works only in context OFSF. There are no degree restrictions on @var{formula}. @rvindex rlcad @end defun @defvr {Advanced Switch} rlcadfac Factorisation. This is on by default. @rvindex rlcadfac @end defvr @defvr Switch rlcadbaseonly Base phase only. Turned off by default. @rvindex rlcadbaseonly @end defvr @defvr Switch rlcadprojonly Projection phase only. Turned off by default. @rvindex rlcadprojonly @end defvr @defvr Switch rlcadextonly Extension phase only. Turned off by default. @rvindex rlcadextonly @end defvr @defvr Switch rlcadpartial Partial CAD. This is turned on by default. @rvindex rlcadpartial @end defvr @defvr {Advanced Switch} rlcadfulldimonly Full dimensional cells only. This is turned off by default. Only stacks over full dimensional cells are built. Such cells have rational sample points. To do this ist sound only in special cases as consistency problems (existenially quantified, strict inequalities). @rvindex rlcadfulldimonly @end defvr @defvr Switch rlcadtrimtree Trim tree. This is turned on by default. Frees unused part of the constructed partial CAD-tree, and hence saves space. However, afterwards it is not possible anymore to find out how many cells were calculated beyond free variable space. @rvindex rlcadtrimtree @end defvr @defvr {Advanced Switch} rlcadrawformula Raw formula. Turned off by default. If turned on, a variable-free DNF is returned (if simple solution formula construction succeeds). Otherwise, the raw result is simplified with @code{rldnf}. @rvindex rlcadrawformula @end defvr @defvr {Advanced Switch} rlcadisoallroots Isolate all roots. This is off by default. Turning this switch on allows to find out, how much time is consumed more without incremental root isolation. @rvindex rlcadisoallroots @end defvr @defvr {Advanced Switch} rlcadrawformula Raw formula. Turned off by default. If turned on, a variable-free DNF is returned (if simple solution formula construction succeeds). Otherwise, the raw result is simplified with @code{rldnf}. @rvindex rlcadrawformula @end defvr @defvr {Advanced Switch} rlcadisoallroots Isolate all roots. This is off by default. Turning this switch on allows to find out, how much time is consumed more without incremental root isolation. @rvindex rlcadisoallroots @end defvr @defvr {Advanced Switch} rlcadaproj @defvrx {Advanced Switch} rlcadaprojalways Augmented projection (always). By default, @code{rlcadaproj} is turned on and @code{rlcadaprojalways} is turned off. If @code{rlcadaproj} is turned off, no augmented projection is performed. Otherwerwise, if turned on, augmented projection is performed always (if @code{rlcadaprojalways} is turned on) or just for the free variable space (@code{rlcadaprojalways} turned off). @rvindex rlcadaproj @rvindex rlcadaprojalways @end defvr @defvr Switch rlcadhongproj Hong projection. This is on by default. If turned on, Hong's improvement for the projection operator is used. @rvindex rlcadhongproj @end defvr @defvr Switch rlcadverbose Verbose. This is off by default. With @code{rladverbose} on, additional verbose information is displayed. @rvindex rlcadverbose @end defvr @defvr Switch rlcaddebug Debug. This is turned off by default. Performes a self-test at several places, if turned on. @rvindex rlcaddebug @end defvr @defvr {Advanced Switch} rlanuexverbose Verbose. This is off by default. With @code{ranuexverbose} on, additional verbose information is displayed. Not of much importance any more. @rvindex rlanuexverbose @end defvr @defvr {Advanced Switch} rlanuexdifferentroots Different roots. Unused for the moment and maybe redundant soon. @rvindex rlanuexdifferentroots @end defvr @defvr Switch rlanuexdebug Debug. This is off by default. Performes a self-test at several places, if turned on. @rvindex rlanuexdebug @end defvr @defvr Switch rlanuexpsremseq Pseudo remainder sequences. This is turned off by default. This switch decides, whether division or pseudo division is used for sturm chains. @rvindex rlanuexpsremseq @end defvr @defvr {Advanced Switch} rlanuexgcdnormalize GCD normalize. This is turned on by default. If turned on, the GCD is normalized to 1, if it is a constant polynomial. @rvindex rlanuexgcdnormalize @end defvr @defvr {Advanced Switch} rlanuexsgnopt Sign optimization. This is turned off by default. If turned on, it is tried to determine the sign of a constant polynomial by calculating a containment. @rvindex rlanuexsgnopt @end defvr @subsection Hermitian Quantifier Elimination @cindex Hermitian quantifier elimination @defun rlhqe formula @cindex quantifier elimination @cindex Hermitian quantifier elimination Hermitian quantifier elimination. Returns a quantifier-free equivalent of @var{formula}. Works only in context @sc{ofsf}. There are no degree restrictions on @var{formula}. @rvindex rlhqe @end defun @node Generic Quantifier Elimination @section Generic Quantifier Elimination The following variant of @code{rlqe} @rfindex rlqe (@pxref{Quantifier Elimination}) enlarges the theory by inequalities, i.e., @code{<>}-atomic formulas, wherever this supports the quantifier elimination process. For geometric problems, @cindex geometric problem it has turned out that in most cases the additional assumptions made are actually geometric @emph{non-degeneracy conditions}. @cindex non-degeneracy conditions The method has been described in detail in @ifinfo @ref{References,[DSW98]}. @end ifinfo @iftex [DSW98]. @end iftex It has also turned out useful for physical problems @cindex physical problems such as network @ifinfo analysis, see @ref{References,[Stu97]}. @end ifinfo @iftex analysis [Stu97]. @cindex network analysis @end iftex @defun rlgqe formula [@var{theory} [@var{exceptionlist}]] @rtindex theory @cindex geometric problem @cindex generic quantifier elimination Generic quantifier elimination. @code{rlgqe} is not available in @sc{acfsf} @cindex @sc{acfsf} and @sc{dvfsf}. @cindex @sc{dvfsf} @var{exceptionlist} is a list of variables empty by default. Returns a list @code{@{th,f@}} such that @code{th} is a superset of @var{theory} adding only inequalities, and @code{f} is a quantifier-free formula equivalent to @var{formula} assuming @code{th}. The added inequalities contain neither bound variables nor variables from @var{exceptionlist}. For restrictions and options, compare @code{rlqe} (@pxref{Quantifier Elimination}). @end defun @defun rlgqea formula [@var{theory} [@var{exceptionlist}]] @rtindex theory @cindex geometric problem @cindex generic quantifier elimination @cindex answer Generic quantifier elimination with answer. @code{rlgqea} is not available in @sc{acfsf} @cindex @sc{acfsf} and @sc{dvfsf}. @cindex @sc{dvfsf} @var{exceptionlist} is a list of variables empty by default. Returns a list consisting of an extended theory @cindex theory @cindex extend theory and an @var{elimination_answer}. @rtindex elimination_answer Compare @code{rlqea}/@code{rlgqe} (@pxref{Quantifier Elimination}). @end defun After applying generic quantifier elimination the user might feel that the result is still too large while the theory is still quite weak. The following function @code{rlgentheo} @rfindex rlgentheo simplifies a formula by making further assumptions. @defun rlgentheo theory formula [@var{exceptionlist}] @rtindex theory @cindex simplification @cindex generic quantifier elimination @cindex generate theory Generate theory. @code{rlgentheo} is not available in @sc{dvfsf}. @cindex @sc{dvfsf} @var{formula} is a quantifier-free formula; @var{exceptionlist} is a list of variables empty by default. @code{rlgentheo} extends @var{theory} @cindex extend theory with inequalities not containing any variables from @var{exceptionlist} as long as the simplification result is better wrt.@: this extended theory. Returns a list @code{@{}extended @var{theory}, simplified @var{formula}@code{@}}. @end defun @defvr Switch rlqegenct @cindex generate theory @cindex complexity of terms Quantifier elimination generate complex theory. @cindex complex theory This is on by default, which allows @code{rlgentheo} @rfindex rlgentheo to assume inequalities over non-monomial terms with the generic quantifier elimination. @end defvr @defun rlgcad formula @rtindex theory @cindex generic cylindrical algebraic decomposition Generic cylindrical algebraic decomposition. @code{rlgcad} is available only for @sc{ofsf}. Compare @code{rlcad} (@pxref{Quantifier Elimination}) and @code{rlgqe} (@pxref{Generic Quantifier Elimination}). @end defun @defun rlghqe formula @rtindex theory @cindex generic Hermitian quantifier elimination Generic Hermitian quantifier elimination. @code{rlghqe} is available only for @sc{ofsf}. Compare @code{rlhqe} (@pxref{Quantifier Elimination}) and @code{rlgqe} (@pxref{Generic Quantifier Elimination}). @end defun @node Local Quantifier Elimination @section Local Quantifier Elimination In contrast to the generic quantifier elimination @rfindex rlgqe (@pxref{Generic Quantifier Elimination}) the following variant of @code{rlqe} @rfindex rlqe (@pxref{Quantifier Elimination}) enlarges the theory by arbitrary atomic formulas, wherever this supports the quantifier elimination process. This is done in such a way that the theory holds for the suggested point specified by the user. The method has been described in detail in @ifinfo @ref{References,[DW00]}. @end ifinfo @iftex [DW00]. @end iftex @defun rllqe formula @var{theory} @var{suggestedpoint} @rtindex theory @cindex local quantifier elimination Local quantifier elimination. @code{rllqe} is not available in @sc{acfsf} @cindex @sc{acfsf} and @sc{dvfsf}. @cindex @sc{dvfsf} @var{suggestedpoint} is a list of equations @code{var=value} where @code{var} is a free variable and @code{value} is a rational number. Returns a list @code{@{th,f@}} such that @code{th} is a superset of @var{theory}, and @code{f} is a quantifier-free formula equivalent to @var{formula} assuming @code{th}. The added inequalities contains exclusively variables occuring on the left hand sides of equiations in @var{suggestedpoint}. For restrictions and options, compare @code{rlqe} (@pxref{Quantifier Elimination}). @end defun @node Linear Optimization @section Linear Optimization In the context @sc{ofsf}, @cindex @sc{ofsf} there is a linear optimization method implemented, which uses quantifier elimination @cindex quantifier elimination (@pxref{Quantifier Elimination}) encoding the target function by an additional constraint @cindex constraint including a dummy variable. This optimization technique has been described in @ifinfo @ref{References,[Wei94a]}. @end ifinfo @iftex [Wei94a]. @end iftex @defun rlopt constraints target @cindex optimization @cindex linear optimization Linear optimization. @code{rlopt} is available only in @sc{ofsf}. @cindex @sc{ofsf} @var{constraints} is a list of parameter-free atomic formulas built with @code{=}, @code{<=}, or @code{>=}; @var{target} is a polynomial over the rationals. @var{target} is minimized subject to @var{constraints}. @cindex constraint The result is either "@code{infeasible}" @cindex @code{infeasible} or a two-element list, the first entry of which is the optimal value, and the second entry is a list of points---each one given as a @var{substitution_list}---where @var{target} @rtindex substitution_list takes this value. The point list does, however, not contain all such points. For unbound problems the result is @w{@code{@{-infinity,@{@}@}}.} @end defun @defvr Switch rlopt1s @cindex optimization @cindex linear optimization @cindex solution Optimization one solution. This is off by default. @code{rlopt1s} is relevant only for @sc{ofsf}. @cindex @sc{ofsf} If on, @code{rlopt} @rfindex rlopt returns at most one solution point. @end defvr @node References @chapter References Most of the references listed here are available on @center @t{http://www.fmi.uni-passau.de/~redlog/}. @table @asis @item [CH91] George E. Collins and Hoon Hong. Partial cylindrical algebraic decomposition for quantifier elimination. @cite{Journal of Symbolic Computation}, 12(3):299-328, September 1991. @item [Dol99] Andreas Dolzmann. Solving Geometric Problems with Real Quantifier Elimination. Technical Report MIP-9903, FMI, Universitaet Passau, D-94030 Passau, Germany, January 1999. @item [DGS98] Andreas Dolzmann, Oliver Gloor, and Thomas Sturm. Approaches to parallel quantifier elimination. In Oliver Gloor, editor, @cite{Proceedings of the 1998 International Symposium on Symbolic and Algebraic Computation (ISSAC 98)}, pages 88-95, Rostock, Germany, August 1998. ACM, ACM Press, New York. @item [DS97] Andreas Dolzmann and Thomas Sturm. Simplification of quantifier-free formulae over ordered fields. @cite{Journal of Symbolic Computation}, 24(2):209-231, August 1997. @item [DS97a] Andreas Dolzmann and Thomas Sturm. Redlog: Computer algebra meets computer logic. @cite{ACM SIGSAM Bulletin}, 31(2):2--9, June 1997. @item [DS97b] Andreas Dolzmann and Thomas Sturm. Guarded expressions in practice. In Wolfgang W. Kuechlin, editor, @cite{Proceedings of the 1997 International Symposium on Symbolic and Algebraic Computation (ISSAC 97)}, pages 376--383, New York, July 1997. ACM, ACM Press. @item [DS99] Andreas Dolzmann and Thomas Sturm. P-adic constraint solving. Technical Report MIP-9901, FMI, Universitaet Passau, D-94030 Passau, Germany, January 1999. To appear in the proceedings of the ISSAC 99. @item [DSW98] Andreas Dolzmann, Thomas Sturm, and Volker Weispfenning. A new approach for automatic theorem proving in real geometry. @cite{Journal of Automated Reasoning}, 21(3):357-380, December 1998. @item [DSW98a] Andreas Dolzmann, Thomas Sturm, and Volker Weispfenning. Real quantifier elimination in practice. In B. H. Matzat, G.-M. Greuel, and G. Hiss, editors, @cite{Algorithmic Algebra and Number Theory}, pages 221-248. Springer, Berlin, 1998. @item [DW00] Andreas Dolzmann and Volker Weispfenning. Local Quantifier Elimination. In Carlo Traverso, editor, @cite{Proceedings of the 2000 International Symposium on Symbolic and Algebraic Computation (ISSAC 00)}, pages 86-94, St Andrews, Scotland, August 2000. ACM, ACM Press, New York. @item [LW93] Ruediger Loos and Volker Weispfenning. Applying linear quantifier elimination. @cite{The Computer Journal}, 36(5):450--462, 1993. Special issue on computational quantifier elimination. @item [Stu97] Thomas Sturm. Reasoning over networks by symbolic methods. Technical Report MIP-9719, FMI, Universitaet Passau, D-94030 Passau, Germany, December 1997. To appear in AAECC. @item [Stu00] Thomas Sturm. Linear problems in valued fields. @cite{Journal of Symbolic Computation}, 30(2):207-219, August 2000. @item [SW97a] Thomas Sturm and Volker Weispfenning. Rounding and blending of solids by a real elimination method. In Achim Sydow, editor, @cite{Proceedings of the 15th IMACS World Congress on Scientific Computation, Modelling, and Applied Mathematics (IMACS 97)}, pages 727-732, Berlin, August 1997. IMACS, Wissenschaft & Technik Verlag. @item [SW98] Thomas Sturm and Volker Weispfenning. Computational geometry problems in Redlog. In Dongming Wang, editor, @cite{Automated Deduction in Geometry}, volume 1360 of Lecture Notes in Artificial Intelligence (Subseries of LNCS), pages 58-86, Springer-Verlag Berlin Heidelberg, 1998. @item [SW98a] Thomas Sturm and Volker Weispfenning. An algebraic approach to offsetting and blending of solids. Technical Report MIP-9804, FMI, Universitaet Passau, D-94030 Passau, Germany, May 1998. @item [Wei88] Volker Weispfenning. The complexity of linear problems in fields. @cite{Journal of Symbolic Computation}, 5(1):3--27, February, 1988. @item [Wei92] Volker Weispfenning. Comprehensive Groebner Bases. @cite{Journal of Symbolic Computation}, 14:1--29, July, 1992. @item [Wei94a] Volker Weispfenning. Parametric linear and quadratic optimization by elimination. Technical Report MIP-9404, FMI, Universitaet Passau, D-94030 Passau, Germany, April 1994. @item [Wei94b] Volker Weispfenning. Quantifier elimination for real algebra---the cubic case. In @cite{Proceedings of the International Symposium on Symbolic and Algebraic Computation in Oxford}, pages 258--263, New York, July 1994. ACM Press. @item [Wei95] Volker Weispfenning. Solving parametric polynomial equations and inequalities by symbolic algorithms. In J. Fleischer et al., editors, @cite{Computer Algebra in Science and Engineering}, pages 163-179, World Scientific, Singapore, 1995. @item [Wei97] Volker Weispfenning. Quantifier elimination for real algebra---the quadratic case and beyond. @cite{Applicable Algebra in Engineering Communication and Computing}, 8(2):85-101, February 1997. @item [Wei97a] Volker Weispfenning. Simulation and optimization by quantifier elimination. @cite{Journal of Symbolic Computation}, 24(2):189-208, August 1997. @end table @node Functions @unnumbered Functions @menu * Documentation of Functions:: * References to Functions:: @end menu @node Documentation of Functions @unnumberedsec Documentation of Functions @printindex fn @node References to Functions @unnumberedsec References to Functions @printindex rf @node Switches and Variables @unnumbered Switches and Variables @menu * Documentation of Switches and Variables:: * References to Switches and Variables:: @end menu @node Documentation of Switches and Variables @unnumberedsec Documentation of Switches and Variables @printindex vr @page @node References to Switches and Variables @unnumberedsec References to Switches and Variables @printindex rv @node Data Structures @unnumbered Data Structures @menu * Documentation of Data Structures:: * References to Data Structures:: @end menu @node Documentation of Data Structures @unnumberedsec Documentation of Data Structures @printindex tp @node References to Data Structures @unnumberedsec References to Data Structures @printindex rt @node Index @unnumbered Index @printindex cp @shortcontents @contents @bye