public void testOverlappedTokensSausage() throws Exception {

    // Two tokens on top of each other (sausage):
    final TokenStream ts =
        new CannedTokenStream(new Token[] {token("abc", 1, 1), token("xyz", 0, 1)});
    final Automaton actual = (new TokenStreamToAutomaton()).toAutomaton(ts);
    final Automaton a1 = BasicAutomata.makeString("abc");
    final Automaton a2 = BasicAutomata.makeString("xyz");
    final Automaton expected = BasicOperations.union(a1, a2);
    assertTrue(BasicOperations.sameLanguage(expected, actual));
  }
 public void testSynHangingOverEnd() throws Exception {
   final TokenStream ts =
       new CannedTokenStream(
           new Token[] {
             token("a", 1, 1), token("X", 0, 10),
           });
   final Automaton actual = (new TokenStreamToAutomaton()).toAutomaton(ts);
   final Automaton expected =
       BasicOperations.union(BasicAutomata.makeString("a"), BasicAutomata.makeString("X"));
   assertTrue(BasicOperations.sameLanguage(expected, actual));
 }
 /** Test a configuration that behaves a lot like KeepWordFilter */
 public void testKeep() throws Exception {
   CharacterRunAutomaton keepWords =
       new CharacterRunAutomaton(
           BasicOperations.complement(
               Automaton.union(
                   Arrays.asList(
                       BasicAutomata.makeString("foo"), BasicAutomata.makeString("bar")))));
   Analyzer a = new MockAnalyzer(MockTokenizer.SIMPLE, true, keepWords, true);
   assertAnalyzesTo(
       a,
       "quick foo brown bar bar fox foo",
       new String[] {"foo", "bar", "bar", "foo"},
       new int[] {2, 2, 1, 2});
 }
Esempio n. 4
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  @Override
  public void setUp() throws Exception {
    super.setUp();
    numIterations = atLeast(50);
    dir = newDirectory();
    RandomIndexWriter writer =
        new RandomIndexWriter(
            random(),
            dir,
            newIndexWriterConfig(
                    TEST_VERSION_CURRENT, new MockAnalyzer(random(), MockTokenizer.KEYWORD, false))
                .setMaxBufferedDocs(_TestUtil.nextInt(random(), 50, 1000)));
    Document doc = new Document();
    Field field = newStringField("field", "", Field.Store.YES);
    doc.add(field);
    terms = new TreeSet<BytesRef>();

    int num = atLeast(200);
    for (int i = 0; i < num; i++) {
      String s = _TestUtil.randomUnicodeString(random());
      field.setStringValue(s);
      terms.add(new BytesRef(s));
      writer.addDocument(doc);
    }

    termsAutomaton = BasicAutomata.makeStringUnion(terms);

    reader = writer.getReader();
    searcher = newSearcher(reader);
    writer.close();
  }
 private Automaton join(String... strings) {
   List<Automaton> as = new ArrayList<Automaton>();
   for (String s : strings) {
     as.add(BasicAutomata.makeString(s));
     as.add(SEP_A);
   }
   as.remove(as.size() - 1);
   return BasicOperations.concatenate(as);
 }
Esempio n. 6
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    /**
     * Create a automaton for a given context query this automaton will be used to find the matching
     * paths with the fst
     *
     * @param preserveSep set an additional char (<code>XAnalyzingSuggester.SEP_LABEL</code>)
     *     between each context query
     * @param queries list of {@link ContextQuery} defining the lookup context
     * @return Automaton matching the given Query
     */
    public static Automaton toAutomaton(boolean preserveSep, Iterable<ContextQuery> queries) {
      Automaton a = BasicAutomata.makeEmptyString();

      Automaton gap = BasicAutomata.makeChar(ContextMapping.SEPARATOR);
      if (preserveSep) {
        // if separators are preserved the fst contains a SEP_LABEL
        // behind each gap. To have a matching automaton, we need to
        // include the SEP_LABEL in the query as well
        gap =
            BasicOperations.concatenate(gap, BasicAutomata.makeChar(XAnalyzingSuggester.SEP_LABEL));
      }

      for (ContextQuery query : queries) {
        a = Automaton.concatenate(Arrays.asList(query.toAutomaton(), gap, a));
      }
      BasicOperations.determinize(a);
      return a;
    }
  public void testSingleToken() throws Exception {

    final TokenStream ts =
        new CannedTokenStream(
            new Token[] {
              token("abc", 1, 1),
            });
    final Automaton actual = (new TokenStreamToAutomaton()).toAutomaton(ts);
    final Automaton expected = BasicAutomata.makeString("abc");
    assertTrue(BasicOperations.sameLanguage(expected, actual));
  }
  public void testSynOverHole2() throws Exception {

    final TokenStream ts =
        new CannedTokenStream(
            new Token[] {
              token("xyz", 1, 1), token("abc", 0, 3), token("def", 2, 1),
            });
    final Automaton actual = (new TokenStreamToAutomaton()).toAutomaton(ts);
    final Automaton expected =
        BasicOperations.union(
            join(s2a("xyz"), SEP_A, HOLE_A, SEP_A, s2a("def")), BasicAutomata.makeString("abc"));
    assertTrue(BasicOperations.sameLanguage(expected, actual));
  }
  public void testOverlappedTokensLattice2() throws Exception {

    final TokenStream ts =
        new CannedTokenStream(
            new Token[] {
              token("abc", 1, 1), token("xyz", 0, 3), token("def", 1, 1), token("ghi", 1, 1),
            });
    final Automaton actual = (new TokenStreamToAutomaton()).toAutomaton(ts);
    final Automaton a1 = BasicAutomata.makeString("xyz");
    final Automaton a2 = join("abc", "def", "ghi");
    final Automaton expected = BasicOperations.union(a1, a2);
    // toDot(actual);
    assertTrue(BasicOperations.sameLanguage(expected, actual));
  }
  public void testSynOverHole() throws Exception {

    final TokenStream ts =
        new CannedTokenStream(
            new Token[] {
              token("a", 1, 1), token("X", 0, 2), token("b", 2, 1),
            });
    final Automaton actual = (new TokenStreamToAutomaton()).toAutomaton(ts);
    final Automaton a1 =
        BasicOperations.union(join(s2a("a"), SEP_A, HOLE_A), BasicAutomata.makeString("X"));
    final Automaton expected = BasicOperations.concatenate(a1, join(SEP_A, s2a("b")));
    // toDot(actual);
    assertTrue(BasicOperations.sameLanguage(expected, actual));
  }
Esempio n. 11
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  /** tests intersect: TODO start at a random term! */
  public void testIntersect() throws Exception {
    for (int i = 0; i < numIterations; i++) {
      String reg = AutomatonTestUtil.randomRegexp(random());
      Automaton automaton = new RegExp(reg, RegExp.NONE).toAutomaton();
      CompiledAutomaton ca =
          new CompiledAutomaton(automaton, SpecialOperations.isFinite(automaton), false);
      TermsEnum te = MultiFields.getTerms(reader, "field").intersect(ca, null);
      Automaton expected = BasicOperations.intersection(termsAutomaton, automaton);
      TreeSet<BytesRef> found = new TreeSet<BytesRef>();
      while (te.next() != null) {
        found.add(BytesRef.deepCopyOf(te.term()));
      }

      Automaton actual = BasicAutomata.makeStringUnion(found);
      assertTrue(BasicOperations.sameLanguage(expected, actual));
    }
  }
Esempio n. 12
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  /** tests a pre-intersected automaton against the original */
  public void testFiniteVersusInfinite() throws Exception {
    for (int i = 0; i < numIterations; i++) {
      String reg = AutomatonTestUtil.randomRegexp(random());
      Automaton automaton = new RegExp(reg, RegExp.NONE).toAutomaton();
      final List<BytesRef> matchedTerms = new ArrayList<BytesRef>();
      for (BytesRef t : terms) {
        if (BasicOperations.run(automaton, t.utf8ToString())) {
          matchedTerms.add(t);
        }
      }

      Automaton alternate = BasicAutomata.makeStringUnion(matchedTerms);
      // System.out.println("match " + matchedTerms.size() + " " + alternate.getNumberOfStates() + "
      // states, sigma=" + alternate.getStartPoints().length);
      // AutomatonTestUtil.minimizeSimple(alternate);
      // System.out.println("minmize done");
      AutomatonQuery a1 = new AutomatonQuery(new Term("field", ""), automaton);
      AutomatonQuery a2 = new AutomatonQuery(new Term("field", ""), alternate);
      CheckHits.checkEqual(
          a1, searcher.search(a1, 25).scoreDocs, searcher.search(a2, 25).scoreDocs);
    }
  }
 private Automaton s2a(String s) {
   return BasicAutomata.makeString(s);
 }
public class TestGraphTokenizers extends BaseTokenStreamTestCase {

  // Makes a graph TokenStream from the string; separate
  // positions with single space, multiple tokens at the same
  // position with /, and add optional position length with
  // :.  EG "a b c" is a simple chain, "a/x b c" adds 'x'
  // over 'a' at position 0 with posLen=1, "a/x:3 b c" adds
  // 'x' over a with posLen=3.  Tokens are in normal-form!
  // So, offsets are computed based on the first token at a
  // given position.  NOTE: each token must be a single
  // character!  We assume this when computing offsets...

  // NOTE: all input tokens must be length 1!!!  This means
  // you cannot turn on MockCharFilter when random
  // testing...

  private static class GraphTokenizer extends Tokenizer {
    private List<Token> tokens;
    private int upto;
    private int inputLength;

    private final CharTermAttribute termAtt = addAttribute(CharTermAttribute.class);
    private final OffsetAttribute offsetAtt = addAttribute(OffsetAttribute.class);
    private final PositionIncrementAttribute posIncrAtt =
        addAttribute(PositionIncrementAttribute.class);
    private final PositionLengthAttribute posLengthAtt =
        addAttribute(PositionLengthAttribute.class);

    @Override
    public void reset() throws IOException {
      super.reset();
      tokens = null;
      upto = 0;
    }

    @Override
    public boolean incrementToken() throws IOException {
      if (tokens == null) {
        fillTokens();
      }
      // System.out.println("graphTokenizer: incr upto=" + upto + " vs " + tokens.size());
      if (upto == tokens.size()) {
        // System.out.println("  END @ " + tokens.size());
        return false;
      }
      final Token t = tokens.get(upto++);
      // System.out.println("  return token=" + t);
      clearAttributes();
      termAtt.append(t.toString());
      offsetAtt.setOffset(t.startOffset(), t.endOffset());
      posIncrAtt.setPositionIncrement(t.getPositionIncrement());
      posLengthAtt.setPositionLength(t.getPositionLength());
      return true;
    }

    @Override
    public void end() throws IOException {
      super.end();
      // NOTE: somewhat... hackish, but we need this to
      // satisfy BTSTC:
      final int lastOffset;
      if (tokens != null && !tokens.isEmpty()) {
        lastOffset = tokens.get(tokens.size() - 1).endOffset();
      } else {
        lastOffset = 0;
      }
      offsetAtt.setOffset(correctOffset(lastOffset), correctOffset(inputLength));
    }

    private void fillTokens() throws IOException {
      final StringBuilder sb = new StringBuilder();
      final char[] buffer = new char[256];
      while (true) {
        final int count = input.read(buffer);
        if (count == -1) {
          break;
        }
        sb.append(buffer, 0, count);
        // System.out.println("got count=" + count);
      }
      // System.out.println("fillTokens: " + sb);

      inputLength = sb.length();

      final String[] parts = sb.toString().split(" ");

      tokens = new ArrayList<Token>();
      int pos = 0;
      int maxPos = -1;
      int offset = 0;
      // System.out.println("again");
      for (String part : parts) {
        final String[] overlapped = part.split("/");
        boolean firstAtPos = true;
        int minPosLength = Integer.MAX_VALUE;
        for (String part2 : overlapped) {
          final int colonIndex = part2.indexOf(':');
          final String token;
          final int posLength;
          if (colonIndex != -1) {
            token = part2.substring(0, colonIndex);
            posLength = Integer.parseInt(part2.substring(1 + colonIndex));
          } else {
            token = part2;
            posLength = 1;
          }
          maxPos = Math.max(maxPos, pos + posLength);
          minPosLength = Math.min(minPosLength, posLength);
          final Token t = new Token(token, offset, offset + 2 * posLength - 1);
          t.setPositionLength(posLength);
          t.setPositionIncrement(firstAtPos ? 1 : 0);
          firstAtPos = false;
          // System.out.println("  add token=" + t + " startOff=" + t.startOffset() + " endOff=" +
          // t.endOffset());
          tokens.add(t);
        }
        pos += minPosLength;
        offset = 2 * pos;
      }
      assert maxPos <= pos : "input string mal-formed: posLength>1 tokens hang over the end";
    }
  }

  public void testMockGraphTokenFilterBasic() throws Exception {

    for (int iter = 0; iter < 10 * RANDOM_MULTIPLIER; iter++) {

      if (VERBOSE) {
        System.out.println("\nTEST: iter=" + iter);
      }

      // Make new analyzer each time, because MGTF has fixed
      // seed:
      final Analyzer a =
          new Analyzer() {
            @Override
            protected TokenStreamComponents createComponents(String fieldName) {
              final Tokenizer t = new MockTokenizer(MockTokenizer.WHITESPACE, false);
              final TokenStream t2 = new MockGraphTokenFilter(random(), t);
              return new TokenStreamComponents(t, t2);
            }
          };

      checkAnalysisConsistency(random(), a, false, "a b c d e f g h i j k");
    }
  }

  public void testMockGraphTokenFilterOnGraphInput() throws Exception {
    for (int iter = 0; iter < 100 * RANDOM_MULTIPLIER; iter++) {

      if (VERBOSE) {
        System.out.println("\nTEST: iter=" + iter);
      }

      // Make new analyzer each time, because MGTF has fixed
      // seed:
      final Analyzer a =
          new Analyzer() {
            @Override
            protected TokenStreamComponents createComponents(String fieldName) {
              final Tokenizer t = new GraphTokenizer();
              final TokenStream t2 = new MockGraphTokenFilter(random(), t);
              return new TokenStreamComponents(t, t2);
            }
          };

      checkAnalysisConsistency(random(), a, false, "a/x:3 c/y:2 d e f/z:4 g h i j k");
    }
  }

  // Just deletes (leaving hole) token 'a':
  private static final class RemoveATokens extends TokenFilter {
    private int pendingPosInc;

    private final CharTermAttribute termAtt = addAttribute(CharTermAttribute.class);
    private final PositionIncrementAttribute posIncAtt =
        addAttribute(PositionIncrementAttribute.class);

    public RemoveATokens(TokenStream in) {
      super(in);
    }

    @Override
    public void reset() throws IOException {
      super.reset();
      pendingPosInc = 0;
    }

    @Override
    public void end() throws IOException {
      super.end();
      posIncAtt.setPositionIncrement(pendingPosInc + posIncAtt.getPositionIncrement());
    }

    @Override
    public boolean incrementToken() throws IOException {
      while (true) {
        final boolean gotOne = input.incrementToken();
        if (!gotOne) {
          return false;
        } else if (termAtt.toString().equals("a")) {
          pendingPosInc += posIncAtt.getPositionIncrement();
        } else {
          posIncAtt.setPositionIncrement(pendingPosInc + posIncAtt.getPositionIncrement());
          pendingPosInc = 0;
          return true;
        }
      }
    }
  }

  public void testMockGraphTokenFilterBeforeHoles() throws Exception {
    for (int iter = 0; iter < 100 * RANDOM_MULTIPLIER; iter++) {

      if (VERBOSE) {
        System.out.println("\nTEST: iter=" + iter);
      }

      // Make new analyzer each time, because MGTF has fixed
      // seed:
      final Analyzer a =
          new Analyzer() {
            @Override
            protected TokenStreamComponents createComponents(String fieldName) {
              final Tokenizer t = new MockTokenizer(MockTokenizer.WHITESPACE, false);
              final TokenStream t2 = new MockGraphTokenFilter(random(), t);
              final TokenStream t3 = new RemoveATokens(t2);
              return new TokenStreamComponents(t, t3);
            }
          };

      Random random = random();
      checkAnalysisConsistency(random, a, false, "a b c d e f g h i j k");
      checkAnalysisConsistency(random, a, false, "x y a b c d e f g h i j k");
      checkAnalysisConsistency(random, a, false, "a b c d e f g h i j k a");
      checkAnalysisConsistency(random, a, false, "a b c d e f g h i j k a x y");
    }
  }

  public void testMockGraphTokenFilterAfterHoles() throws Exception {
    for (int iter = 0; iter < 100 * RANDOM_MULTIPLIER; iter++) {

      if (VERBOSE) {
        System.out.println("\nTEST: iter=" + iter);
      }

      // Make new analyzer each time, because MGTF has fixed
      // seed:
      final Analyzer a =
          new Analyzer() {
            @Override
            protected TokenStreamComponents createComponents(String fieldName) {
              final Tokenizer t = new MockTokenizer(MockTokenizer.WHITESPACE, false);
              final TokenStream t2 = new RemoveATokens(t);
              final TokenStream t3 = new MockGraphTokenFilter(random(), t2);
              return new TokenStreamComponents(t, t3);
            }
          };

      Random random = random();
      checkAnalysisConsistency(random, a, false, "a b c d e f g h i j k");
      checkAnalysisConsistency(random, a, false, "x y a b c d e f g h i j k");
      checkAnalysisConsistency(random, a, false, "a b c d e f g h i j k a");
      checkAnalysisConsistency(random, a, false, "a b c d e f g h i j k a x y");
    }
  }

  public void testMockGraphTokenFilterRandom() throws Exception {
    for (int iter = 0; iter < 10 * RANDOM_MULTIPLIER; iter++) {

      if (VERBOSE) {
        System.out.println("\nTEST: iter=" + iter);
      }

      // Make new analyzer each time, because MGTF has fixed
      // seed:
      final Analyzer a =
          new Analyzer() {
            @Override
            protected TokenStreamComponents createComponents(String fieldName) {
              final Tokenizer t = new MockTokenizer(MockTokenizer.WHITESPACE, false);
              final TokenStream t2 = new MockGraphTokenFilter(random(), t);
              return new TokenStreamComponents(t, t2);
            }
          };

      Random random = random();
      checkRandomData(random, a, 5, atLeast(100));
    }
  }

  // Two MockGraphTokenFilters
  public void testDoubleMockGraphTokenFilterRandom() throws Exception {
    for (int iter = 0; iter < 10 * RANDOM_MULTIPLIER; iter++) {

      if (VERBOSE) {
        System.out.println("\nTEST: iter=" + iter);
      }

      // Make new analyzer each time, because MGTF has fixed
      // seed:
      final Analyzer a =
          new Analyzer() {
            @Override
            protected TokenStreamComponents createComponents(String fieldName) {
              final Tokenizer t = new MockTokenizer(MockTokenizer.WHITESPACE, false);
              final TokenStream t1 = new MockGraphTokenFilter(random(), t);
              final TokenStream t2 = new MockGraphTokenFilter(random(), t1);
              return new TokenStreamComponents(t, t2);
            }
          };

      Random random = random();
      checkRandomData(random, a, 5, atLeast(100));
    }
  }

  public void testMockGraphTokenFilterBeforeHolesRandom() throws Exception {
    for (int iter = 0; iter < 10 * RANDOM_MULTIPLIER; iter++) {

      if (VERBOSE) {
        System.out.println("\nTEST: iter=" + iter);
      }

      // Make new analyzer each time, because MGTF has fixed
      // seed:
      final Analyzer a =
          new Analyzer() {
            @Override
            protected TokenStreamComponents createComponents(String fieldName) {
              final Tokenizer t = new MockTokenizer(MockTokenizer.WHITESPACE, false);
              final TokenStream t1 = new MockGraphTokenFilter(random(), t);
              final TokenStream t2 = new MockHoleInjectingTokenFilter(random(), t1);
              return new TokenStreamComponents(t, t2);
            }
          };

      Random random = random();
      checkRandomData(random, a, 5, atLeast(100));
    }
  }

  public void testMockGraphTokenFilterAfterHolesRandom() throws Exception {
    for (int iter = 0; iter < 10 * RANDOM_MULTIPLIER; iter++) {

      if (VERBOSE) {
        System.out.println("\nTEST: iter=" + iter);
      }

      // Make new analyzer each time, because MGTF has fixed
      // seed:
      final Analyzer a =
          new Analyzer() {
            @Override
            protected TokenStreamComponents createComponents(String fieldName) {
              final Tokenizer t = new MockTokenizer(MockTokenizer.WHITESPACE, false);
              final TokenStream t1 = new MockHoleInjectingTokenFilter(random(), t);
              final TokenStream t2 = new MockGraphTokenFilter(random(), t1);
              return new TokenStreamComponents(t, t2);
            }
          };

      Random random = random();
      checkRandomData(random, a, 5, atLeast(100));
    }
  }

  private static Token token(String term, int posInc, int posLength) {
    final Token t = new Token(term, 0, 0);
    t.setPositionIncrement(posInc);
    t.setPositionLength(posLength);
    return t;
  }

  private static Token token(
      String term, int posInc, int posLength, int startOffset, int endOffset) {
    final Token t = new Token(term, startOffset, endOffset);
    t.setPositionIncrement(posInc);
    t.setPositionLength(posLength);
    return t;
  }

  public void testSingleToken() throws Exception {

    final TokenStream ts =
        new CannedTokenStream(
            new Token[] {
              token("abc", 1, 1),
            });
    final Automaton actual = (new TokenStreamToAutomaton()).toAutomaton(ts);
    final Automaton expected = BasicAutomata.makeString("abc");
    assertTrue(BasicOperations.sameLanguage(expected, actual));
  }

  public void testMultipleHoles() throws Exception {
    final TokenStream ts =
        new CannedTokenStream(
            new Token[] {
              token("a", 1, 1), token("b", 3, 1),
            });
    final Automaton actual = (new TokenStreamToAutomaton()).toAutomaton(ts);
    final Automaton expected = join(s2a("a"), SEP_A, HOLE_A, SEP_A, HOLE_A, SEP_A, s2a("b"));
    assertTrue(BasicOperations.sameLanguage(expected, actual));
  }

  public void testSynOverMultipleHoles() throws Exception {
    final TokenStream ts =
        new CannedTokenStream(
            new Token[] {
              token("a", 1, 1), token("x", 0, 3), token("b", 3, 1),
            });
    final Automaton actual = (new TokenStreamToAutomaton()).toAutomaton(ts);
    final Automaton a1 = join(s2a("a"), SEP_A, HOLE_A, SEP_A, HOLE_A, SEP_A, s2a("b"));
    final Automaton a2 = join(s2a("x"), SEP_A, s2a("b"));
    final Automaton expected = BasicOperations.union(a1, a2);
    assertTrue(BasicOperations.sameLanguage(expected, actual));
  }

  // for debugging!
  /*
  private static void toDot(Automaton a) throws IOException {
    final String s = a.toDot();
    Writer w = new OutputStreamWriter(new FileOutputStream("/x/tmp/out.dot"));
    w.write(s);
    w.close();
    System.out.println("TEST: saved to /x/tmp/out.dot");
  }
  */

  private static final Automaton SEP_A = BasicAutomata.makeChar(TokenStreamToAutomaton.POS_SEP);
  private static final Automaton HOLE_A = BasicAutomata.makeChar(TokenStreamToAutomaton.HOLE);

  private Automaton join(String... strings) {
    List<Automaton> as = new ArrayList<Automaton>();
    for (String s : strings) {
      as.add(BasicAutomata.makeString(s));
      as.add(SEP_A);
    }
    as.remove(as.size() - 1);
    return BasicOperations.concatenate(as);
  }

  private Automaton join(Automaton... as) {
    return BasicOperations.concatenate(Arrays.asList(as));
  }

  private Automaton s2a(String s) {
    return BasicAutomata.makeString(s);
  }

  public void testTwoTokens() throws Exception {

    final TokenStream ts =
        new CannedTokenStream(
            new Token[] {
              token("abc", 1, 1), token("def", 1, 1),
            });
    final Automaton actual = (new TokenStreamToAutomaton()).toAutomaton(ts);
    final Automaton expected = join("abc", "def");

    // toDot(actual);
    assertTrue(BasicOperations.sameLanguage(expected, actual));
  }

  public void testHole() throws Exception {

    final TokenStream ts =
        new CannedTokenStream(
            new Token[] {
              token("abc", 1, 1), token("def", 2, 1),
            });
    final Automaton actual = (new TokenStreamToAutomaton()).toAutomaton(ts);

    final Automaton expected = join(s2a("abc"), SEP_A, HOLE_A, SEP_A, s2a("def"));

    // toDot(actual);
    assertTrue(BasicOperations.sameLanguage(expected, actual));
  }

  public void testOverlappedTokensSausage() throws Exception {

    // Two tokens on top of each other (sausage):
    final TokenStream ts =
        new CannedTokenStream(new Token[] {token("abc", 1, 1), token("xyz", 0, 1)});
    final Automaton actual = (new TokenStreamToAutomaton()).toAutomaton(ts);
    final Automaton a1 = BasicAutomata.makeString("abc");
    final Automaton a2 = BasicAutomata.makeString("xyz");
    final Automaton expected = BasicOperations.union(a1, a2);
    assertTrue(BasicOperations.sameLanguage(expected, actual));
  }

  public void testOverlappedTokensLattice() throws Exception {

    final TokenStream ts =
        new CannedTokenStream(
            new Token[] {
              token("abc", 1, 1), token("xyz", 0, 2), token("def", 1, 1),
            });
    final Automaton actual = (new TokenStreamToAutomaton()).toAutomaton(ts);
    final Automaton a1 = BasicAutomata.makeString("xyz");
    final Automaton a2 = join("abc", "def");

    final Automaton expected = BasicOperations.union(a1, a2);
    // toDot(actual);
    assertTrue(BasicOperations.sameLanguage(expected, actual));
  }

  public void testSynOverHole() throws Exception {

    final TokenStream ts =
        new CannedTokenStream(
            new Token[] {
              token("a", 1, 1), token("X", 0, 2), token("b", 2, 1),
            });
    final Automaton actual = (new TokenStreamToAutomaton()).toAutomaton(ts);
    final Automaton a1 =
        BasicOperations.union(join(s2a("a"), SEP_A, HOLE_A), BasicAutomata.makeString("X"));
    final Automaton expected = BasicOperations.concatenate(a1, join(SEP_A, s2a("b")));
    // toDot(actual);
    assertTrue(BasicOperations.sameLanguage(expected, actual));
  }

  public void testSynOverHole2() throws Exception {

    final TokenStream ts =
        new CannedTokenStream(
            new Token[] {
              token("xyz", 1, 1), token("abc", 0, 3), token("def", 2, 1),
            });
    final Automaton actual = (new TokenStreamToAutomaton()).toAutomaton(ts);
    final Automaton expected =
        BasicOperations.union(
            join(s2a("xyz"), SEP_A, HOLE_A, SEP_A, s2a("def")), BasicAutomata.makeString("abc"));
    assertTrue(BasicOperations.sameLanguage(expected, actual));
  }

  public void testOverlappedTokensLattice2() throws Exception {

    final TokenStream ts =
        new CannedTokenStream(
            new Token[] {
              token("abc", 1, 1), token("xyz", 0, 3), token("def", 1, 1), token("ghi", 1, 1),
            });
    final Automaton actual = (new TokenStreamToAutomaton()).toAutomaton(ts);
    final Automaton a1 = BasicAutomata.makeString("xyz");
    final Automaton a2 = join("abc", "def", "ghi");
    final Automaton expected = BasicOperations.union(a1, a2);
    // toDot(actual);
    assertTrue(BasicOperations.sameLanguage(expected, actual));
  }

  public void testToDot() throws Exception {
    final TokenStream ts = new CannedTokenStream(new Token[] {token("abc", 1, 1, 0, 4)});
    StringWriter w = new StringWriter();
    new TokenStreamToDot("abcd", ts, new PrintWriter(w)).toDot();
    assertTrue(w.toString().indexOf("abc / abcd") != -1);
  }

  public void testStartsWithHole() throws Exception {
    final TokenStream ts =
        new CannedTokenStream(
            new Token[] {
              token("abc", 2, 1),
            });
    final Automaton actual = (new TokenStreamToAutomaton()).toAutomaton(ts);
    final Automaton expected = join(HOLE_A, SEP_A, s2a("abc"));
    // toDot(actual);
    assertTrue(BasicOperations.sameLanguage(expected, actual));
  }

  // TODO: testEndsWithHole... but we need posInc to set in TS.end()

  public void testSynHangingOverEnd() throws Exception {
    final TokenStream ts =
        new CannedTokenStream(
            new Token[] {
              token("a", 1, 1), token("X", 0, 10),
            });
    final Automaton actual = (new TokenStreamToAutomaton()).toAutomaton(ts);
    final Automaton expected =
        BasicOperations.union(BasicAutomata.makeString("a"), BasicAutomata.makeString("X"));
    assertTrue(BasicOperations.sameLanguage(expected, actual));
  }
}
  /**
   * Extracts all MultiTermQueries for {@code field}, and returns equivalent automata that will
   * match terms.
   */
  static CharacterRunAutomaton[] extractAutomata(Query query, String field) {
    List<CharacterRunAutomaton> list = new ArrayList<>();
    if (query instanceof BooleanQuery) {
      BooleanClause clauses[] = ((BooleanQuery) query).getClauses();
      for (BooleanClause clause : clauses) {
        if (!clause.isProhibited()) {
          list.addAll(Arrays.asList(extractAutomata(clause.getQuery(), field)));
        }
      }
    } else if (query instanceof DisjunctionMaxQuery) {
      for (Query sub : ((DisjunctionMaxQuery) query).getDisjuncts()) {
        list.addAll(Arrays.asList(extractAutomata(sub, field)));
      }
    } else if (query instanceof SpanOrQuery) {
      for (Query sub : ((SpanOrQuery) query).getClauses()) {
        list.addAll(Arrays.asList(extractAutomata(sub, field)));
      }
    } else if (query instanceof SpanNearQuery) {
      for (Query sub : ((SpanNearQuery) query).getClauses()) {
        list.addAll(Arrays.asList(extractAutomata(sub, field)));
      }
    } else if (query instanceof SpanNotQuery) {
      list.addAll(Arrays.asList(extractAutomata(((SpanNotQuery) query).getInclude(), field)));
    } else if (query instanceof SpanPositionCheckQuery) {
      list.addAll(
          Arrays.asList(extractAutomata(((SpanPositionCheckQuery) query).getMatch(), field)));
    } else if (query instanceof SpanMultiTermQueryWrapper) {
      list.addAll(
          Arrays.asList(
              extractAutomata(((SpanMultiTermQueryWrapper<?>) query).getWrappedQuery(), field)));
    } else if (query instanceof AutomatonQuery) {
      final AutomatonQuery aq = (AutomatonQuery) query;
      if (aq.getField().equals(field)) {
        list.add(
            new CharacterRunAutomaton(aq.getAutomaton()) {
              @Override
              public String toString() {
                return aq.toString();
              }
            });
      }
    } else if (query instanceof PrefixQuery) {
      final PrefixQuery pq = (PrefixQuery) query;
      Term prefix = pq.getPrefix();
      if (prefix.field().equals(field)) {
        list.add(
            new CharacterRunAutomaton(
                BasicOperations.concatenate(
                    BasicAutomata.makeString(prefix.text()), BasicAutomata.makeAnyString())) {
              @Override
              public String toString() {
                return pq.toString();
              }
            });
      }
    } else if (query instanceof FuzzyQuery) {
      final FuzzyQuery fq = (FuzzyQuery) query;
      if (fq.getField().equals(field)) {
        String utf16 = fq.getTerm().text();
        int termText[] = new int[utf16.codePointCount(0, utf16.length())];
        for (int cp, i = 0, j = 0; i < utf16.length(); i += Character.charCount(cp)) {
          termText[j++] = cp = utf16.codePointAt(i);
        }
        int termLength = termText.length;
        int prefixLength = Math.min(fq.getPrefixLength(), termLength);
        String suffix =
            UnicodeUtil.newString(termText, prefixLength, termText.length - prefixLength);
        LevenshteinAutomata builder = new LevenshteinAutomata(suffix, fq.getTranspositions());
        Automaton automaton = builder.toAutomaton(fq.getMaxEdits());
        if (prefixLength > 0) {
          Automaton prefix =
              BasicAutomata.makeString(UnicodeUtil.newString(termText, 0, prefixLength));
          automaton = BasicOperations.concatenate(prefix, automaton);
        }
        list.add(
            new CharacterRunAutomaton(automaton) {
              @Override
              public String toString() {
                return fq.toString();
              }
            });
      }
    } else if (query instanceof TermRangeQuery) {
      final TermRangeQuery tq = (TermRangeQuery) query;
      if (tq.getField().equals(field)) {
        final CharsRef lowerBound;
        if (tq.getLowerTerm() == null) {
          lowerBound = null;
        } else {
          lowerBound = new CharsRef(tq.getLowerTerm().utf8ToString());
        }

        final CharsRef upperBound;
        if (tq.getUpperTerm() == null) {
          upperBound = null;
        } else {
          upperBound = new CharsRef(tq.getUpperTerm().utf8ToString());
        }

        final boolean includeLower = tq.includesLower();
        final boolean includeUpper = tq.includesUpper();
        final CharsRef scratch = new CharsRef();
        final Comparator<CharsRef> comparator = CharsRef.getUTF16SortedAsUTF8Comparator();

        // this is *not* an automaton, but its very simple
        list.add(
            new CharacterRunAutomaton(BasicAutomata.makeEmpty()) {
              @Override
              public boolean run(char[] s, int offset, int length) {
                scratch.chars = s;
                scratch.offset = offset;
                scratch.length = length;

                if (lowerBound != null) {
                  int cmp = comparator.compare(scratch, lowerBound);
                  if (cmp < 0 || (!includeLower && cmp == 0)) {
                    return false;
                  }
                }

                if (upperBound != null) {
                  int cmp = comparator.compare(scratch, upperBound);
                  if (cmp > 0 || (!includeUpper && cmp == 0)) {
                    return false;
                  }
                }
                return true;
              }

              @Override
              public String toString() {
                return tq.toString();
              }
            });
      }
    }
    return list.toArray(new CharacterRunAutomaton[list.size()]);
  }