1 /*
2  * [The "BSD license"]
3  *  Copyright (c) 2010 Terence Parr
4  *  All rights reserved.
5  *
6  *  Redistribution and use in source and binary forms, with or without
7  *  modification, are permitted provided that the following conditions
8  *  are met:
9  *  1. Redistributions of source code must retain the above copyright
10  *      notice, this list of conditions and the following disclaimer.
11  *  2. Redistributions in binary form must reproduce the above copyright
12  *      notice, this list of conditions and the following disclaimer in the
13  *      documentation and/or other materials provided with the distribution.
14  *  3. The name of the author may not be used to endorse or promote products
15  *      derived from this software without specific prior written permission.
16  *
17  *  THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR
18  *  IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES
19  *  OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED.
20  *  IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT,
21  *  INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT
22  *  NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
23  *  DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
24  *  THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
25  *  (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF
26  *  THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
27  */
28 package org.antlr.analysis;
29 
30 import org.antlr.misc.IntSet;
31 import org.antlr.misc.IntervalSet;
32 import org.antlr.tool.Grammar;
33 
34 /** A state machine transition label.  A label can be either a simple
35  *  label such as a token or character.  A label can be a set of char or
36  *  tokens.  It can be an epsilon transition.  It can be a semantic predicate
37  *  (which assumes an epsilon transition) or a tree of predicates (in a DFA).
38  *  Special label types have to be < 0 to avoid conflict with char.
39  */
40 public class Label implements Comparable, Cloneable {
41     public static final int INVALID = -7;
42 
43 	public static final int ACTION = -6;
44 
45 	public static final int EPSILON = -5;
46 
47     public static final String EPSILON_STR = "<EPSILON>";
48 
49     /** label is a semantic predicate; implies label is epsilon also */
50     public static final int SEMPRED = -4;
51 
52     /** label is a set of tokens or char */
53     public static final int SET = -3;
54 
55     /** End of Token is like EOF for lexer rules.  It implies that no more
56      *  characters are available and that NFA conversion should terminate
57      *  for this path.  For example
58      *
59      *  A : 'a' 'b' | 'a' ;
60      *
61      *  yields a DFA predictor:
62      *
63      *  o-a->o-b->1   predict alt 1
64      *       |
65      *       |-EOT->o predict alt 2
66      *
67      *  To generate code for EOT, treat it as the "default" path, which
68      *  implies there is no way to mismatch a char for the state from
69      *  which the EOT emanates.
70      */
71     public static final int EOT = -2;
72 
73     public static final int EOF = -1;
74 
75 	/** We have labels like EPSILON that are below 0; it's hard to
76 	 *  store them in an array with negative index so use this
77 	 *  constant as an index shift when accessing arrays based upon
78 	 *  token type.  If real token type is i, then array index would be
79 	 *  NUM_FAUX_LABELS + i.
80 	 */
81 	public static final int NUM_FAUX_LABELS = -INVALID;
82 
83     /** Anything at this value or larger can be considered a simple atom int
84      *  for easy comparison during analysis only; faux labels are not used
85 	 *  during parse time for real token types or char values.
86      */
87     public static final int MIN_ATOM_VALUE = EOT;
88 
89     // TODO: is 0 a valid unicode char? max is FFFF -1, right?
90     public static final int MIN_CHAR_VALUE = '\u0000';
91     public static final int MAX_CHAR_VALUE = '\uFFFF';
92 
93 	/** End of rule token type; imaginary token type used only for
94 	 *  local, partial FOLLOW sets to indicate that the local FOLLOW
95 	 *  hit the end of rule.  During error recovery, the local FOLLOW
96 	 *  of a token reference may go beyond the end of the rule and have
97 	 *  to use FOLLOW(rule).  I have to just shift the token types to 2..n
98 	 *  rather than 1..n to accommodate this imaginary token in my bitsets.
99 	 *  If I didn't use a bitset implementation for runtime sets, I wouldn't
100 	 *  need this.  EOF is another candidate for a run time token type for
101 	 *  parsers.  Follow sets are not computed for lexers so we do not have
102 	 *  this issue.
103 	 */
104 	public static final int EOR_TOKEN_TYPE =
105 		org.antlr.runtime.Token.EOR_TOKEN_TYPE;
106 
107 	public static final int DOWN = org.antlr.runtime.Token.DOWN;
108 	public static final int UP = org.antlr.runtime.Token.UP;
109 
110     /** tokens and char range overlap; tokens are MIN_TOKEN_TYPE..n */
111 	public static final int MIN_TOKEN_TYPE =
112 		org.antlr.runtime.Token.MIN_TOKEN_TYPE;
113 
114     /** The wildcard '.' char atom implies all valid characters==UNICODE */
115     //public static final IntSet ALLCHAR = IntervalSet.of(MIN_CHAR_VALUE,MAX_CHAR_VALUE);
116 
117     /** The token type or character value; or, signifies special label. */
118     protected int label;
119 
120     /** A set of token types or character codes if label==SET */
121 	// TODO: try IntervalSet for everything
122     protected IntSet labelSet;
123 
Label(int label)124     public Label(int label) {
125         this.label = label;
126     }
127 
128     /** Make a set label */
Label(IntSet labelSet)129     public Label(IntSet labelSet) {
130 		if ( labelSet==null ) {
131 			this.label = SET;
132 			this.labelSet = IntervalSet.of(INVALID);
133 			return;
134 		}
135 		int singleAtom = labelSet.getSingleElement();
136         if ( singleAtom!=INVALID ) {
137             // convert back to a single atomic element if |labelSet|==1
138             label = singleAtom;
139             return;
140         }
141         this.label = SET;
142         this.labelSet = labelSet;
143     }
144 
clone()145 	public Object clone() {
146 		Label l;
147 		try {
148 			l = (Label)super.clone();
149 			l.label = this.label;
150             l.labelSet = new IntervalSet();
151 			l.labelSet.addAll(this.labelSet);
152 		}
153 		catch (CloneNotSupportedException e) {
154 			throw new InternalError();
155 		}
156 		return l;
157 	}
158 
add(Label a)159 	public void add(Label a) {
160 		if ( isAtom() ) {
161 			labelSet = IntervalSet.of(label);
162 			label=SET;
163 			if ( a.isAtom() ) {
164 				labelSet.add(a.getAtom());
165 			}
166 			else if ( a.isSet() ) {
167 				labelSet.addAll(a.getSet());
168 			}
169 			else {
170 				throw new IllegalStateException("can't add element to Label of type "+label);
171 			}
172 			return;
173 		}
174 		if ( isSet() ) {
175 			if ( a.isAtom() ) {
176 				labelSet.add(a.getAtom());
177 			}
178 			else if ( a.isSet() ) {
179 				labelSet.addAll(a.getSet());
180 			}
181 			else {
182 				throw new IllegalStateException("can't add element to Label of type "+label);
183 			}
184 			return;
185 		}
186 		throw new IllegalStateException("can't add element to Label of type "+label);
187 	}
188 
isAtom()189     public boolean isAtom() {
190         return label>=MIN_ATOM_VALUE;
191     }
192 
isEpsilon()193     public boolean isEpsilon() {
194         return label==EPSILON;
195     }
196 
isSemanticPredicate()197 	public boolean isSemanticPredicate() {
198 		return false;
199 	}
200 
isAction()201 	public boolean isAction() {
202 		return false;
203 	}
204 
isSet()205     public boolean isSet() {
206         return label==SET;
207     }
208 
209     /** return the single atom label or INVALID if not a single atom */
getAtom()210     public int getAtom() {
211         if ( isAtom() ) {
212             return label;
213         }
214         return INVALID;
215     }
216 
getSet()217     public IntSet getSet() {
218         if ( label!=SET ) {
219             // convert single element to a set if they ask for it.
220             return IntervalSet.of(label);
221         }
222         return labelSet;
223     }
224 
setSet(IntSet set)225     public void setSet(IntSet set) {
226         label=SET;
227         labelSet = set;
228     }
229 
getSemanticContext()230     public SemanticContext getSemanticContext() {
231         return null;
232     }
233 
matches(int atom)234 	public boolean matches(int atom) {
235 		if ( label==atom ) {
236 			return true; // handle the single atom case efficiently
237 		}
238 		if ( isSet() ) {
239 			return labelSet.member(atom);
240 		}
241 		return false;
242 	}
243 
matches(IntSet set)244 	public boolean matches(IntSet set) {
245 		if ( isAtom() ) {
246 			return set.member(getAtom());
247 		}
248 		if ( isSet() ) {
249 			// matches if intersection non-nil
250 			return !getSet().and(set).isNil();
251 		}
252 		return false;
253 	}
254 
255 
matches(Label other)256 	public boolean matches(Label other) {
257 		if ( other.isSet() ) {
258 			return matches(other.getSet());
259 		}
260 		if ( other.isAtom() ) {
261 			return matches(other.getAtom());
262 		}
263 		return false;
264 	}
265 
hashCode()266     public int hashCode() {
267         if (label==SET) {
268             return labelSet.hashCode();
269 		}
270 		else {
271 			return label;
272 		}
273 	}
274 
275 	// TODO: do we care about comparing set {A} with atom A? Doesn't now.
equals(Object o)276 	public boolean equals(Object o) {
277 		if ( o==null ) {
278 			return false;
279 		}
280 		if ( this == o ) {
281 			return true; // equals if same object
282 		}
283 		// labels must be the same even if epsilon or set or sempred etc...
284         if ( label!=((Label)o).label ) {
285             return false;
286         }
287 		if ( label==SET ) {
288 			return this.labelSet.equals(((Label)o).labelSet);
289 		}
290 		return true;  // label values are same, so true
291     }
292 
compareTo(Object o)293     public int compareTo(Object o) {
294         return this.label-((Label)o).label;
295     }
296 
297     /** Predicates are lists of AST nodes from the NFA created from the
298      *  grammar, but the same predicate could be cut/paste into multiple
299      *  places in the grammar.  I must compare the text of all the
300      *  predicates to truly answer whether {p1,p2} .equals {p1,p2}.
301      *  Unfortunately, I cannot rely on the AST.equals() to work properly
302      *  so I must do a brute force O(n^2) nested traversal of the Set
303      *  doing a String compare.
304      *
305      *  At this point, Labels are not compared for equals when they are
306      *  predicates, but here's the code for future use.
307      */
308     /*
309     protected boolean predicatesEquals(Set others) {
310         Iterator iter = semanticContext.iterator();
311         while (iter.hasNext()) {
312             AST predAST = (AST) iter.next();
313             Iterator inner = semanticContext.iterator();
314             while (inner.hasNext()) {
315                 AST otherPredAST = (AST) inner.next();
316                 if ( !predAST.getText().equals(otherPredAST.getText()) ) {
317                     return false;
318                 }
319             }
320         }
321         return true;
322     }
323       */
324 
toString()325     public String toString() {
326         switch (label) {
327             case SET :
328                 return labelSet.toString();
329             default :
330                 return String.valueOf(label);
331         }
332     }
333 
toString(Grammar g)334     public String toString(Grammar g) {
335         switch (label) {
336             case SET :
337                 return labelSet.toString(g);
338             default :
339                 return g.getTokenDisplayName(label);
340         }
341     }
342 
343     /*
344     public String predicatesToString() {
345         if ( semanticContext==NFAConfiguration.DEFAULT_CLAUSE_SEMANTIC_CONTEXT ) {
346             return "!other preds";
347         }
348         StringBuffer buf = new StringBuffer();
349         Iterator iter = semanticContext.iterator();
350         while (iter.hasNext()) {
351             AST predAST = (AST) iter.next();
352             buf.append(predAST.getText());
353             if ( iter.hasNext() ) {
354                 buf.append("&");
355             }
356         }
357         return buf.toString();
358     }
359     */
360 
intersect(Label label, Label edgeLabel)361 	public static boolean intersect(Label label, Label edgeLabel) {
362 		boolean hasIntersection = false;
363 		boolean labelIsSet = label.isSet();
364 		boolean edgeIsSet = edgeLabel.isSet();
365 		if ( !labelIsSet && !edgeIsSet && edgeLabel.label==label.label ) {
366 			hasIntersection = true;
367 		}
368 		else if ( labelIsSet && edgeIsSet &&
369 				  !edgeLabel.getSet().and(label.getSet()).isNil() ) {
370 			hasIntersection = true;
371 		}
372 		else if ( labelIsSet && !edgeIsSet &&
373 				  label.getSet().member(edgeLabel.label) ) {
374 			hasIntersection = true;
375 		}
376 		else if ( !labelIsSet && edgeIsSet &&
377 				  edgeLabel.getSet().member(label.label) ) {
378 			hasIntersection = true;
379 		}
380 		return hasIntersection;
381 	}
382 }
383