- Documentation
- Reference manual
- The SWI-Prolog library
- library(aggregate): Aggregation operators on backtrackable predicates
- library(ansi_term): Print decorated text to ANSI consoles
- library(apply): Apply predicates on a list
- library(assoc): Association lists
- library(broadcast): Broadcast and receive event notifications
- library(charsio): I/O on Lists of Character Codes
- library(check): Consistency checking
- library(clpb): CLP(B): Constraint Logic Programming over Boolean Variables
- library(clpfd): CLP(FD): Constraint Logic Programming over Finite Domains
- library(clpqr): Constraint Logic Programming over Rationals and Reals
- library(csv): Process CSV (Comma-Separated Values) data
- library(dcg/basics): Various general DCG utilities
- library(dcg/high_order): High order grammar operations
- library(debug): Print debug messages and test assertions
- library(dicts): Dict utilities
- library(error): Error generating support
- library(gensym): Generate unique identifiers
- library(intercept): Intercept and signal interface
- library(iostream): Utilities to deal with streams
- library(listing): List programs and pretty print clauses
- library(lists): List Manipulation
- library(main): Provide entry point for scripts
- library(nb_set): Non-backtrackable set
- library(www_browser): Activating your Web-browser
- library(occurs): Finding and counting sub-terms
- library(option): Option list processing
- library(optparse): command line parsing
- library(ordsets): Ordered set manipulation
- library(pairs): Operations on key-value lists
- library(persistency): Provide persistent dynamic predicates
- library(pio): Pure I/O
- library(predicate_options): Declare option-processing of predicates
- library(prolog_jiti): Just In Time Indexing (JITI) utilities
- library(prolog_pack): A package manager for Prolog
- library(prolog_xref): Prolog cross-referencer data collection
- library(quasi_quotations): Define Quasi Quotation syntax
- library(random): Random numbers
- library(readutil): Read utilities
- library(record): Access named fields in a term
- library(registry): Manipulating the Windows registry
- library(settings): Setting management
- library(strings): String utilities
- library(simplex): Solve linear programming problems
- library(solution_sequences): Modify solution sequences
- library(tables): XSB interface to tables
- library(terms): Term manipulation
- library(thread): High level thread primitives
- library(thread_pool): Resource bounded thread management
- library(ugraphs): Unweighted Graphs
- library(url): Analysing and constructing URL
- library(varnumbers): Utilities for numbered terms
- library(yall): Lambda expressions
- The SWI-Prolog library
- Packages
- Reference manual
A.10 library(clpqr): Constraint Logic Programming over Rationals and Reals
Author: Christian Holzbaur, ported to SWI-Prolog by Leslie De Koninck, K.U. Leuven
This CLP(Q,R) system is a port of the CLP(Q,R) system of Sicstus Prolog by Christian Holzbaur: Holzbaur C.: OFAI clp(q,r) Manual, Edition 1.3.3, Austrian Research Institute for Artificial Intelligence, Vienna, TR-95-09, 1995.207http://www.ai.univie.ac.at/cgi-bin/tr-online?number+95-09 This manual is roughly based on the manual of the above mentioned CLP(Q,R) implementation.
The CLP(Q,R) system consists of two components: the CLP(Q) library for handling constraints over the rational numbers and the CLP(R) library for handling constraints over the real numbers (using floating point numbers as representation). Both libraries offer the same predicates (with exception of bb_inf/4 in CLP(Q) and bb_inf/5 in CLP(R)). It is allowed to use both libraries in one program, but using both CLP(Q) and CLP(R) constraints on the same variable will result in an exception.
Please note that the library(clpqr)
library is not
an
autoload library and therefore this library must be loaded
explicitly before using it:
:- use_module(library(clpq)).
or
:- use_module(library(clpr)).
A.10.1 Solver predicates
The following predicates are provided to work with constraints:- {}(+Constraints)
- Adds the constraints given by Constraints to the constraint store.
- entailed(+Constraint)
- Succeeds if Constraint is necessarily true within the current constraint store. This means that adding the negation of the constraint to the store results in failure.
- inf(+Expression, -Inf)
- Computes the infimum of Expression within the current state of the constraint store and returns that infimum in Inf. This predicate does not change the constraint store.
- sup(+Expression, -Sup)
- Computes the supremum of Expression within the current state of the constraint store and returns that supremum in Sup. This predicate does not change the constraint store.
- minimize(+Expression)
- Minimizes Expression within the current constraint store. This is the same as computing the infimum and equating the expression to that infimum.
- maximize(+Expression)
- Maximizes Expression within the current constraint store. This is the same as computing the supremum and equating the expression to that supremum.
- bb_inf(+Ints, +Expression, -Inf, -Vertex, +Eps)
- This predicate is offered in CLP(R) only. It computes the infimum of Expression within the current constraint store, with the additional constraint that in that infimum, all variables in Ints have integral values. Vertex will contain the values of Ints in the infimum. Eps denotes how much a value may differ from an integer to be considered an integer. E.g. when Eps = 0.001, then X = 4.999 will be considered as an integer (5 in this case). Eps should be between 0 and 0.5.
- bb_inf(+Ints, +Expression, -Inf, -Vertex)
- This predicate is offered in CLP(Q) only. It behaves the same as bb_inf/5 but does not use an error margin.
- bb_inf(+Ints, +Expression, -Inf)
- The same as bb_inf/5 or bb_inf/4 but without returning the values of the integers. In CLP(R), an error margin of 0.001 is used.
- dump(+Target, +Newvars, -CodedAnswer)
- Returns the constraints on Target in the list CodedAnswer
where all variables of Target have been replaced by NewVars.
This operation does not change the constraint store. E.g. in
dump([X,Y,Z],[x,y,z],Cons)
Cons
will contain the constraints on X, Y and Z, where these variables have been replaced by atoms x, y and z.
A.10.2 Syntax of the predicate arguments
The arguments of the predicates defined in the subsection above are defined in table 10. Failing to meet the syntax rules will result in an exception.<Constraints> | ::= | <Constraint> | single constraint |
| | <Constraint> , <Constraints> | conjunction | |
| | <Constraint> ; <Constraints> | disjunction | |
<Constraint> | ::= | <Expression> < <Expression> | less than |
| | <Expression> > <Expression> | greater than | |
| | <Expression> =< <Expression> | less or equal | |
| | <= (<Expression>, <Expression>) | less or equal | |
| | <Expression> >= <Expression> | greater or equal | |
| | <Expression> =\= <Expression> | not equal | |
| | <Expression> =:= <Expression> | equal | |
| | <Expression> = <Expression> | equal | |
<Expression> | ::= | <Variable> | Prolog variable |
| | <Number> | Prolog number | |
| | +<Expression> | unary plus | |
| | -<Expression> | unary minus | |
| | <Expression> + <Expression> | addition | |
| | <Expression> - <Expression> | substraction | |
| | <Expression> * <Expression> | multiplication | |
| | <Expression> / <Expression> | division | |
| | abs(<Expression>) | absolute value | |
| | sin(<Expression>) | sine | |
| | cos(<Expression>) | cosine | |
| | tan(<Expression>) | tangent | |
| | exp(<Expression>) | exponent | |
| | pow(<Expression>) | exponent | |
| | <Expression> ^ <Expression> | exponent | |
| | min(<Expression>, <Expression>) | minimum | |
| | max(<Expression>, <Expression>) | maximum |
A.10.3 Use of unification
Instead of using the {}/1 predicate, you can also use the standard unification mechanism to store constraints. The following code samples are equivalent:
- Unification with a variable
{X =:= Y} {X = Y} X = Y
- Unification with a number
{X =:= 5.0} {X = 5.0} X = 5.0
A.10.4 Non-linear constraints
The CLP(Q,R) system deals only passively with non-linear constraints. They remain in a passive state until certain conditions are satisfied. These conditions, which are called the isolation axioms, are given in table 11.A = B * C | B or C is ground | A = 5 * C or A = B * 4 |
A and (B or C) are ground | 20 = 5 * C or 20 = B * 4 | |
A = B / C | C is ground | A = B / 3 |
A and B are ground | 4 = 12 / C | |
X = min(Y,Z) | Y and Z are ground | X = min(4,3) |
X = max(Y,Z) | Y and Z are ground | X = max(4,3) |
X = abs(Y) | Y is ground | X = abs(-7) |
X = pow(Y,Z) | X and Y are ground | 8 = 2 ^ Z |
X = exp(Y,Z) | X and Z are ground | 8 =
Y ^ 3 |
X = Y ^ Z | Y and Z are ground | X = 2 ^ 3 |
X = sin(Y) | X is ground | 1 = sin(Y) |
X = cos(Y) | Y is ground | X = sin(1.5707) |
X = tan(Y) |
A.10.5 Status and known problems
The clpq and clpr libraries are‘orphaned', i.e., they currently have no maintainer.
- Top-level output
The top-level output may contain variables not present in the original query:?- {X+Y>=1}. {Y=1-X+_G2160, _G2160>=0}. ?-
Nonetheless, for linear constraints this kind of answer means unconditional satisfiability.
- Dumping constraints
The first argument of dump/3 has to be a list of free variables at call-time:?- {X=1},dump([X],[Y],L). ERROR: Unhandled exception: Unknown message: instantiation_error(dump([1],[_G11],_G6),1) ?-