src/lang/VariableTerm.java - prolog-cafe - Git at Google

 package com.googlecode.prolog_cafe.lang;

 import com.googlecode.prolog_cafe.exceptions.InternalException;

 /**
  * Variable.<br>
  * The <code>VariableTerm</code> class represents a logical variable.<br>
  * For example,
  * <pre>
  *   Term t = new VariableTerm();
  * </pre>
  *
  * @author Mutsunori Banbara (banbara@kobe-u.ac.jp)
  * @author Naoyuki Tamura (tamura@kobe-u.ac.jp)
  * @version 1.0
  */
 public class VariableTerm extends Term implements Undoable {
     /** Holds a term to which this variable is bound. Initial value is <code>this</code> (self-reference). */
     private Term val;
     /** A CPF time stamp when this object is newly constructed. */
     private long timeStamp;

     /** Constructs a new logical variable so that
      * the <code>timeStamp</code> field is set to <code>Long.MIN_VALUE</code>.
      */
     public VariableTerm() {
 	val = this;
     timeStamp = Long.MIN_VALUE;
     }

     /** Constructs a new logical variable so that
      * the <code>timeStamp</code> field is set to the current value of
      * <code>CPFTimeStamp</code> of the specified Prolog engine.
      * @param engine Current Prolog engine.
      * @see Prolog#getCPFTimeStamp
      */
     public VariableTerm(Prolog engine) {
 	val = this;
 	timeStamp = engine.getCPFTimeStamp();
     }

     /** Returns a string representation of this object.*/
     protected String variableName() { return "_" + Integer.toHexString(hashCode()).toUpperCase(); }

     /* Term */
     /**
      * Checks whether the argument term is unified with this one.
      * If this is an unbound variable, the <code>unify</code> method binds this to
      * the dereferenced value of argument term: <code>bind(t.dereference(), trail)</code>,
      * and returns <code>true</code>.
      * Otherwise, it returns a <code>boolean</code> whose value is <code>val.unify(t, trail)</code>.
      * @param t the term to be unified with.
      * @param trail Trail Stack.
      * @return <code>true</code> if succeeds, otherwise <code>false</code>.
      * @see #val
      * @see #bind(Term,Trail)
      * @see Trail
      */
     public boolean unify(Term t, Trail trail) {
 	if (val != this)
 	    return val.unify(t, trail);
 	t = t.dereference();
 	if (this != t)
 	    bind(t, trail);
 	return true;
     }

     /**
      * Binds this variable to a given term.
      * And pushs this variable to trail stack if necessary.
      * @param t a term to be bound.
      * @param trail Trail Stack
      * @see Trail
      */
   public void bind(Term t, Trail trail) {
     if (t instanceof VariableTerm) {
       VariableTerm v = (VariableTerm) t;
       if (v.timeStamp >= this.timeStamp) {
         v.val = this;
         if (v.timeStamp < trail.timeStamp)
           trail.push(v);
         return;
       }
     }

     val = t;
     if (timeStamp < trail.timeStamp)
       trail.push(this);
   }

     /**
      * Checks whether this object is convertible with the given Java class type
      * if this variable is unbound.
      * Otherwise, returns the value of <code>val.convertible(type)</code>.
      * @param type the Java class type to compare with.
      * @return <code>true</code> if this (or dereferenced term) is
      * convertible with <code>type</code>. Otherwise <code>false</code>.
      * @see #val
      */
     public boolean convertible(Class type) {
 	if (val != this)
 	    return val.convertible(type);
 	return convertible(this.getClass(), type);
     }

     /**
      * Returns a copy of this object if unbound variable.
      * Otherwise, returns the value of <code>val.copy(engine)</code>.
      * @see #val
      */
     protected Term copy(Prolog engine) {
 	VariableTerm co;
 	if (val != this)
 	    return val.copy(engine);
 	co = engine.copyHash.get(this);
 	if (co == null) {
 	    //	    co = new VariableTerm(engine);
 	    co = new VariableTerm();
 	    engine.copyHash.put(this, co);
 	}
 	return co;
     }

     public Term dereference() {
 	if (val == this)
 	    return this;
 	return val.dereference();
     }

     public boolean isGround() {
 	if (val != this)
 	    return val.isGround();
 	return false;
     }

     public String name() {
     if (val == this)
       return "";
     return val.dereference().name();
     }

     /**
      * Returns <code>this</code> if this variable is unbound.
      * Otherwise, returns a Java object that corresponds to the dereferenced term:
      * <code>val.toJava()</code>.
      * @return a Java object defined in <em>Prolog Cafe interoperability with Java</em>.
      * @see #val
      */
     public Object toJava() {
 	if (val != this)
 	    return val.toJava();
 	return this;
     }

     /**
      * Returns a quoted string representation of this term if unbound.
      * Otherwise, returns the value of dereferenced term:
      * <code>val.toQuotedString()</code>
      * @see #val
      */
     public String toQuotedString() {
 	if (val != this)
 	    return val.toQuotedString();
 	return variableName();
     }

     /* Object */
     /**
      * Checks <em>term equality</em> of two terms.
      * This method returns a <code>boolean</code> whose value is
      * (<code>this == obj</code>) if this variable is unbound.
      * Otherwise, it returns the value of <code>val.equals(obj)</code>.
      * @param obj the object to compare with. This must be dereferenced.
      * @return <code>true</code> if this (or dereferenced term) is the same as the argument;
      * <code>false</code> otherwise.
      * @see #val
      * @see #compareTo
     */
     public boolean equals(Object obj) {
 	if(val != this)
 	    return val.equals(obj);
 	if (! (obj instanceof VariableTerm)) // ???
 	    return false; //???
 	return this == obj;
     }

     /**
      * Returns a string representation of this term if unbound.
      * Otherwise, returns the value of dereferenced term:
      * <code>val.toString()</code>
      * @see #val
      */
     public String toString() {
 	if (val != this)
 	    return val.toString();
 	return variableName();
     }

     /* Undoable */
     public void undo() { val = this; }

     /* Comparable */
     /**
      * Compares two terms in <em>Prolog standard order of terms</em>.<br>
      * It is noted that <code>t1.compareTo(t2) == 0</code> has the same
      * <code>boolean</code> value as <code>t1.equals(t2)</code>.
      * @param anotherTerm the term to compare with. It must be dereferenced.
      * @return the value <code>0</code> if two terms are identical;
      * a value less than <code>0</code> if this term is <em>before</em> the <code>anotherTerm</code>;
      * and a value greater than <code>0</code> if this term is <em>after</em> the <code>anotherTerm</code>.
      */
     public int compareTo(Term anotherTerm) { // anotherTerm must be dereferenced.
 	if(val != this)
 	    return val.compareTo(anotherTerm);
 	if (! (anotherTerm instanceof VariableTerm))
 	    return BEFORE;
 	if (this == anotherTerm)
 	    return EQUAL;
 	int x = this.hashCode() - ((VariableTerm)anotherTerm).hashCode();
 	if (x != 0)
 	    return x;
 	throw new InternalException("VariableTerm is not unique");
     }
 }
	package com.googlecode.prolog_cafe.lang;

	import com.googlecode.prolog_cafe.exceptions.InternalException;

	/**
	* Variable.<br>
	* The <code>VariableTerm</code> class represents a logical variable.<br>
	* For example,
	* <pre>
	* Term t = new VariableTerm();
	* </pre>
	*
	* @author Mutsunori Banbara (banbara@kobe-u.ac.jp)
	* @author Naoyuki Tamura (tamura@kobe-u.ac.jp)
	* @version 1.0
	*/
	public class VariableTerm extends Term implements Undoable {
	/** Holds a term to which this variable is bound. Initial value is <code>this</code> (self-reference). */
	private Term val;
	/** A CPF time stamp when this object is newly constructed. */
	private long timeStamp;

	/** Constructs a new logical variable so that
	* the <code>timeStamp</code> field is set to <code>Long.MIN_VALUE</code>.
	*/
	public VariableTerm() {
	val = this;
	timeStamp = Long.MIN_VALUE;
	}

	/** Constructs a new logical variable so that
	* the <code>timeStamp</code> field is set to the current value of
	* <code>CPFTimeStamp</code> of the specified Prolog engine.
	* @param engine Current Prolog engine.
	* @see Prolog#getCPFTimeStamp
	*/
	public VariableTerm(Prolog engine) {
	val = this;
	timeStamp = engine.getCPFTimeStamp();
	}

	/** Returns a string representation of this object.*/
	protected String variableName() { return "_" + Integer.toHexString(hashCode()).toUpperCase(); }

	/* Term */
	/**
	* Checks whether the argument term is unified with this one.
	* If this is an unbound variable, the <code>unify</code> method binds this to
	* the dereferenced value of argument term: <code>bind(t.dereference(), trail)</code>,
	* and returns <code>true</code>.
	* Otherwise, it returns a <code>boolean</code> whose value is <code>val.unify(t, trail)</code>.
	* @param t the term to be unified with.
	* @param trail Trail Stack.
	* @return <code>true</code> if succeeds, otherwise <code>false</code>.
	* @see #val
	* @see #bind(Term,Trail)
	* @see Trail
	*/
	public boolean unify(Term t, Trail trail) {
	if (val != this)
	return val.unify(t, trail);
	t = t.dereference();
	if (this != t)
	bind(t, trail);
	return true;
	}

	/**
	* Binds this variable to a given term.
	* And pushs this variable to trail stack if necessary.
	* @param t a term to be bound.
	* @param trail Trail Stack
	* @see Trail
	*/
	public void bind(Term t, Trail trail) {
	if (t instanceof VariableTerm) {
	VariableTerm v = (VariableTerm) t;
	if (v.timeStamp >= this.timeStamp) {
	v.val = this;
	if (v.timeStamp < trail.timeStamp)
	trail.push(v);
	return;
	}
	}

	val = t;
	if (timeStamp < trail.timeStamp)
	trail.push(this);
	}

	/**
	* Checks whether this object is convertible with the given Java class type
	* if this variable is unbound.
	* Otherwise, returns the value of <code>val.convertible(type)</code>.
	* @param type the Java class type to compare with.
	* @return <code>true</code> if this (or dereferenced term) is
	* convertible with <code>type</code>. Otherwise <code>false</code>.
	* @see #val
	*/
	public boolean convertible(Class type) {
	if (val != this)
	return val.convertible(type);
	return convertible(this.getClass(), type);
	}

	/**
	* Returns a copy of this object if unbound variable.
	* Otherwise, returns the value of <code>val.copy(engine)</code>.
	* @see #val
	*/
	protected Term copy(Prolog engine) {
	VariableTerm co;
	if (val != this)
	return val.copy(engine);
	co = engine.copyHash.get(this);
	if (co == null) {
	// co = new VariableTerm(engine);
	co = new VariableTerm();
	engine.copyHash.put(this, co);
	}
	return co;
	}

	public Term dereference() {
	if (val == this)
	return this;
	return val.dereference();
	}

	public boolean isGround() {
	if (val != this)
	return val.isGround();
	return false;
	}

	public String name() {
	if (val == this)
	return "";
	return val.dereference().name();
	}

	/**
	* Returns <code>this</code> if this variable is unbound.
	* Otherwise, returns a Java object that corresponds to the dereferenced term:
	* <code>val.toJava()</code>.
	* @return a Java object defined in <em>Prolog Cafe interoperability with Java</em>.
	* @see #val
	*/
	public Object toJava() {
	if (val != this)
	return val.toJava();
	return this;
	}

	/**
	* Returns a quoted string representation of this term if unbound.
	* Otherwise, returns the value of dereferenced term:
	* <code>val.toQuotedString()</code>
	* @see #val
	*/
	public String toQuotedString() {
	if (val != this)
	return val.toQuotedString();
	return variableName();
	}

	/* Object */
	/**
	* Checks <em>term equality</em> of two terms.
	* This method returns a <code>boolean</code> whose value is
	* (<code>this == obj</code>) if this variable is unbound.
	* Otherwise, it returns the value of <code>val.equals(obj)</code>.
	* @param obj the object to compare with. This must be dereferenced.
	* @return <code>true</code> if this (or dereferenced term) is the same as the argument;
	* <code>false</code> otherwise.
	* @see #val
	* @see #compareTo
	*/
	public boolean equals(Object obj) {
	if(val != this)
	return val.equals(obj);
	if (! (obj instanceof VariableTerm)) // ???
	return false; //???
	return this == obj;
	}

	/**
	* Returns a string representation of this term if unbound.
	* Otherwise, returns the value of dereferenced term:
	* <code>val.toString()</code>
	* @see #val
	*/
	public String toString() {
	if (val != this)
	return val.toString();
	return variableName();
	}

	/* Undoable */
	public void undo() { val = this; }

	/* Comparable */
	/**
	* Compares two terms in <em>Prolog standard order of terms</em>.<br>
	* It is noted that <code>t1.compareTo(t2) == 0</code> has the same
	* <code>boolean</code> value as <code>t1.equals(t2)</code>.
	* @param anotherTerm the term to compare with. It must be dereferenced.
	* @return the value <code>0</code> if two terms are identical;
	* a value less than <code>0</code> if this term is <em>before</em> the <code>anotherTerm</code>;
	* and a value greater than <code>0</code> if this term is <em>after</em> the <code>anotherTerm</code>.
	*/
	public int compareTo(Term anotherTerm) { // anotherTerm must be dereferenced.
	if(val != this)
	return val.compareTo(anotherTerm);
	if (! (anotherTerm instanceof VariableTerm))
	return BEFORE;
	if (this == anotherTerm)
	return EQUAL;
	int x = this.hashCode() - ((VariableTerm)anotherTerm).hashCode();
	if (x != 0)
	return x;
	throw new InternalException("VariableTerm is not unique");
	}
	}