//tabstop=4 //*****************************************************************************/ // Project: jpl // // File: $Id: Compound.java,v 1.1 2004-08-27 20:27:56 vsc Exp $ // Date: $Date: 2004-08-27 20:27:56 $ // Author: Fred Dushin // // // Description: // // // ------------------------------------------------------------------------- // Copyright (c) 2004 Paul Singleton // Copyright (c) 1998 Fred Dushin // All rights reserved. // // This library is free software; you can redistribute it and/or // modify it under the terms of the GNU Library Public License // as published by the Free Software Foundation; either version 2 // of the License, or (at your option) any later version. // // This library is distributed in the hope that it will be useful, // but WITHOUT ANY WARRANTY; without even the implied warranty of // MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the // GNU Library Public License for more details. //*****************************************************************************/ package jpl; import java.util.Map; import jpl.fli.IntHolder; import jpl.fli.Prolog; import jpl.fli.StringHolder; import jpl.fli.term_t; //----------------------------------------------------------------------/ // Compound /** * A Compound represents a structured term, * comprising a functor and arguments (Terms). * Atom is a subclass of Compound, whose instances have zero arguments. * Direct instances of Compound must have one or more arguments * (it is an error to attempt to construct a Compound with zero args; * a JPLException will be thrown). * For example, this Java expression yields * a representation of the term f(a): * 
 * new Compound( "f", new Term[] { new Atom("a") } )
 *
* Note the use of the "anonymous array" notation to denote the arguments * (an anonymous array of Term). *
* Alternatively, construct the Term from Prolog source syntax: * 
 * Util.textToTerm("f(a)")
 *
* The arity of a Compound is the quantity of its arguments. * Once constructed, neither the name, arity nor any argument of a Compound can be altered. *
* Copyright (C) 2004 Paul Singleton

* Copyright (C) 1998 Fred Dushin

* * This library is free software; you can redistribute it and/or * modify it under the terms of the GNU Library Public License * as published by the Free Software Foundation; either version 2 * of the License, or (at your option) any later version.

* * This library is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU Library Public License for more details.

*

* @author Fred Dushin * @version $Revision: 1.1 $ * @see jpl.Term * @see jpl.Atom */ public class Compound extends Term { //==================================================================/ // Attributes //==================================================================/ /** * the name of this Compound */ protected final String name; /** * the arguments of this Compound */ protected final Term[] args; //==================================================================/ // Constructors //==================================================================/ /** * Creates a Compound with name but no args (i.e. an Atom). * * @param name the name of this Compound * @param args the arguments of this Compound */ protected Compound(String name) { if (name == null) { throw new JPLException("jpl.Atom: cannot construct with null name"); } this.name = name; this.args = new Term[] { }; } /** * Creates a Compound with name and args. * * @param name the name of this Compound * @param args the arguments of this Compound */ public Compound(String name, Term[] args) { if (name == null) { throw new JPLException("jpl.Compound: cannot construct with null name"); } if (args == null) { throw new JPLException("jpl.Compound: cannot construct with null args"); } if (args.length == 0) { throw new JPLException("jpl.Compound: cannot construct with zero args"); } this.name = name; this.args = args; } //==================================================================/ // Methods (common) //==================================================================/ /** * Returns the ith argument (counting from 1) of this Compound; * throws an ArrayIndexOutOfBoundsException if i is inappropriate. * * @return the ith argument (counting from 1) of this Compound */ public final Term arg(int i) { return args[i - 1]; } /** * Tests whether this Compound's functor has (String) 'name' and 'arity'. * * @return whether this Compound's functor has (String) 'name' and 'arity' */ public final boolean hasFunctor(String name, int arity) { return name.equals(name) && arity == args.length; } /** * Returns the name (unquoted) of this Compound. * * @return the name (unquoted) of this Compound */ public final String name() { return name; } /** * Returns the arity (1+) of this Compound. * * @return the arity (1+) of this Compound */ public final int arity() { return args.length; } /** * Returns a prefix functional representation of a Compound of the form name(arg1,...), * where each argument is represented according to its toString() method. *
* NB 'name' should be quoted iff necessary, and Term.toString(Term[]) is not * really a Term method, more a utility... * * @return string representation of an Compound */ public String toString() { return quotedName() + (args.length > 0 ? "(" + Term.toString(args) + ")" : ""); } /** * Two Compounds are equal if they are identical (same object) or their names and arities are equal and their * respective arguments are equal. * * @param obj the Object to compare (not necessarily another Compound) * @return true if the Object satisfies the above condition */ public final boolean equals(Object obj) { return (this == obj || (obj instanceof Compound && name.equals(((Compound) obj).name) && Term.terms_equals(args, ((Compound) obj).args))); } public int type() { return Prolog.COMPOUND; } public String typeName(){ return "Compound"; } //==================================================================/ // Methods (protected) //==================================================================/ /** * Returns a quoted (iff necessary) form of the Atom's name, as understood by Prolog read/1 * * @return a quoted form of the Atom's name, as understood by Prolog read/1 */ protected String quotedName() { return ((Atom) (new Query(new Compound("sformat", new Term[] { new Variable("S"), new Atom("~q"), new Compound(".", new Term[] { new Atom(this.name), new Atom("[]")}) }))) .oneSolution() .get( "S")).name; } //==================================================================/ // Methods (deprecated) //==================================================================/ /** * Returns the arguments of this Compound. * * @return the arguments of this Compound * @deprecated */ public final Term[] args() { return args; } /** * Returns the ith argument (counting from 0) of this Compound. * * @return the ith argument (counting from 0) of this Compound * @deprecated */ public final Term arg0(int i) { return args[i]; } /** * Returns a debug-friendly representation of a Compound. * * @return a debug-friendly representation of a Compound * @deprecated */ public String debugString() { return "(Compound " + name + " " + Term.debugString(args) + ")"; } //==================================================================/ // Converting JPL Terms to Prolog terms //==================================================================/ /** * To put a Compound in a term, we create a sequence of term_t * references from the Term.terms_to_term_ts() method, and then * use the Prolog.cons_functor_v() method to create a Prolog compound * term. * * @param varnames_to_vars A Map from variable names to Prolog variables * @param term A (previously created) term_t which is to be * set to a Prolog term corresponding to the Term subtype * (Atom, Variable, Compound, etc.) on which the method is invoked. */ protected final void put(Map varnames_to_vars, term_t term) { Prolog.cons_functor_v(term, Prolog.new_functor(Prolog.new_atom(name), args.length), Term.putTerms(varnames_to_vars, args)); } //==================================================================/ // Converting Prolog terms to JPL Terms //==================================================================/ /** * Converts the Prolog term in term_t (known to be a compound) to a JPL Compound. * In this case, we create a list of Terms by calling Term.getTerm for each * term_t reference we get from Prolog.get_arg * (Not sure why we couldn't get a sequence from there, but...).

* * @param varnames_to_vars A Map from variable names to Prolog variables * @param term The Prolog term to convert * @return A new Compound */ protected static Term getTerm(Map varnames_to_vars, term_t term) { // we need holders to get the term's name and arity back from the FLI: StringHolder name_holder = new StringHolder(); IntHolder arity_holder = new IntHolder(); Prolog.get_name_arity(term, name_holder, arity_holder); // assume it succeeds Term args[] = new Term[arity_holder.value]; for (int i = 1; i <= arity_holder.value; i++) { term_t termi = Prolog.new_term_ref(); Prolog.get_arg(i, term, termi); args[i - 1] = Term.getTerm(varnames_to_vars, termi); } return new Compound(name_holder.value, args); } //==================================================================/ // Computing Substitutions //==================================================================/ /** * Nothing needs to be done except to pass the buck to this Compound's args. * * @param varnames_to_Terms A Map from variable names to JPL Terms * @param vars_to_Vars A Map from Prolog variables to JPL Variables */ protected final void getSubst(Map varnames_to_Terms, Map vars_to_Vars) { Term.getSubsts(varnames_to_Terms, vars_to_Vars, args); } } //345678901234567890123456789012346578901234567890123456789012345678901234567890