private static void testAllSlices(
     String id,
     NavigableSet<Integer> btree,
     NavigableSet<Integer> canon,
     boolean ascending,
     List<ListenableFuture<?>> results) {
   testOneSlice(id, btree, canon, results);
   for (Integer lb : range(canon.size(), Integer.MIN_VALUE, ascending)) {
     // test head/tail sets
     testOneSlice(
         String.format("%s->[..%d)", id, lb),
         btree.headSet(lb, true),
         canon.headSet(lb, true),
         results);
     testOneSlice(
         String.format("%s->(..%d)", id, lb),
         btree.headSet(lb, false),
         canon.headSet(lb, false),
         results);
     testOneSlice(
         String.format("%s->(%d..]", id, lb),
         btree.tailSet(lb, true),
         canon.tailSet(lb, true),
         results);
     testOneSlice(
         String.format("%s->(%d..]", id, lb),
         btree.tailSet(lb, false),
         canon.tailSet(lb, false),
         results);
     for (Integer ub : range(canon.size(), lb, ascending)) {
       // test subsets
       testOneSlice(
           String.format("%s->[%d..%d]", id, lb, ub),
           btree.subSet(lb, true, ub, true),
           canon.subSet(lb, true, ub, true),
           results);
       testOneSlice(
           String.format("%s->(%d..%d]", id, lb, ub),
           btree.subSet(lb, false, ub, true),
           canon.subSet(lb, false, ub, true),
           results);
       testOneSlice(
           String.format("%s->[%d..%d)", id, lb, ub),
           btree.subSet(lb, true, ub, false),
           canon.subSet(lb, true, ub, false),
           results);
       testOneSlice(
           String.format("%s->(%d..%d)", id, lb, ub),
           btree.subSet(lb, false, ub, false),
           canon.subSet(lb, false, ub, false),
           results);
     }
   }
 }
示例#2
0
  /** tailSet returns set with keys in requested range */
  public void testDescendingTailSetContents() {
    NavigableSet set = dset5();
    SortedSet sm = set.tailSet(m2);
    assertFalse(sm.contains(m1));
    assertTrue(sm.contains(m2));
    assertTrue(sm.contains(m3));
    assertTrue(sm.contains(m4));
    assertTrue(sm.contains(m5));
    Iterator i = sm.iterator();
    Object k;
    k = (Integer) (i.next());
    assertEquals(m2, k);
    k = (Integer) (i.next());
    assertEquals(m3, k);
    k = (Integer) (i.next());
    assertEquals(m4, k);
    k = (Integer) (i.next());
    assertEquals(m5, k);
    assertFalse(i.hasNext());

    SortedSet ssm = sm.tailSet(m4);
    assertEquals(m4, ssm.first());
    assertEquals(m5, ssm.last());
    assertTrue(ssm.remove(m4));
    assertEquals(1, ssm.size());
    assertEquals(3, sm.size());
    assertEquals(4, set.size());
  }
示例#3
0
  /** tailSet returns set with keys in requested range */
  public void testTailSetContents() {
    NavigableSet set = set5();
    SortedSet sm = set.tailSet(two);
    assertFalse(sm.contains(one));
    assertTrue(sm.contains(two));
    assertTrue(sm.contains(three));
    assertTrue(sm.contains(four));
    assertTrue(sm.contains(five));
    Iterator i = sm.iterator();
    Object k;
    k = (Integer) (i.next());
    assertEquals(two, k);
    k = (Integer) (i.next());
    assertEquals(three, k);
    k = (Integer) (i.next());
    assertEquals(four, k);
    k = (Integer) (i.next());
    assertEquals(five, k);
    assertFalse(i.hasNext());

    SortedSet ssm = sm.tailSet(four);
    assertEquals(four, ssm.first());
    assertEquals(five, ssm.last());
    assertTrue(ssm.remove(four));
    assertEquals(1, ssm.size());
    assertEquals(3, sm.size());
    assertEquals(4, set.size());
  }
示例#4
0
文件: SetsTest.java 项目: cjosw/guava
  @GwtIncompatible("NavigableSet")
  public void testUnmodifiableNavigableSet() {
    TreeSet<Integer> mod = Sets.newTreeSet();
    mod.add(1);
    mod.add(2);
    mod.add(3);

    NavigableSet<Integer> unmod = unmodifiableNavigableSet(mod);

    /* Unmodifiable is a view. */
    mod.add(4);
    assertTrue(unmod.contains(4));
    assertTrue(unmod.descendingSet().contains(4));

    ensureNotDirectlyModifiable(unmod);
    ensureNotDirectlyModifiable(unmod.descendingSet());
    ensureNotDirectlyModifiable(unmod.headSet(2));
    ensureNotDirectlyModifiable(unmod.headSet(2, true));
    ensureNotDirectlyModifiable(unmod.tailSet(2));
    ensureNotDirectlyModifiable(unmod.tailSet(2, true));
    ensureNotDirectlyModifiable(unmod.subSet(1, 3));
    ensureNotDirectlyModifiable(unmod.subSet(1, true, 3, true));

    /* UnsupportedOperationException on indirect modifications. */
    NavigableSet<Integer> reverse = unmod.descendingSet();
    try {
      reverse.add(4);
      fail("UnsupportedOperationException expected");
    } catch (UnsupportedOperationException expected) {
    }
    try {
      reverse.addAll(Collections.singleton(4));
      fail("UnsupportedOperationException expected");
    } catch (UnsupportedOperationException expected) {
    }
    try {
      reverse.remove(4);
      fail("UnsupportedOperationException expected");
    } catch (UnsupportedOperationException expected) {
    }
  }
  @SuppressWarnings("EmptyCatchBlock")
  public void testUnmodifiability() {
    TreeSet<Integer> mod = Sets.newTreeSet();
    mod.add(1);
    mod.add(2);
    mod.add(3);

    NavigableSet<Integer> unmod = new UnmodifiableNavigableSet<Integer>(mod);

    mod.add(4);
    assertTrue(unmod.contains(4));
    assertTrue(unmod.descendingSet().contains(4));

    ensureNotDirectlyModifiable(unmod);
    ensureNotDirectlyModifiable(unmod.descendingSet());
    ensureNotDirectlyModifiable(unmod.headSet(2));
    ensureNotDirectlyModifiable(unmod.headSet(2, true));
    ensureNotDirectlyModifiable(unmod.tailSet(2));
    ensureNotDirectlyModifiable(unmod.tailSet(2, true));
    ensureNotDirectlyModifiable(unmod.subSet(1, 3));
    ensureNotDirectlyModifiable(unmod.subSet(1, true, 3, true));

    NavigableSet<Integer> reverse = unmod.descendingSet();
    try {
      reverse.add(4);
      fail("UnsupportedOperationException expected");
    } catch (UnsupportedOperationException expected) {
    }
    try {
      reverse.addAll(Collections.singleton(4));
      fail("UnsupportedOperationException expected");
    } catch (UnsupportedOperationException expected) {
    }
    try {
      reverse.remove(4);
      fail("UnsupportedOperationException expected");
    } catch (UnsupportedOperationException expected) {
    }
  }
示例#6
0
  /**
   * Finds range of server deltas needed to transform against, then transforms all client ops
   * against the server ops.
   */
  private VersionedWaveletDelta transformSubmittedDelta(
      WaveletDelta submittedDelta, HashedVersion appliedVersion)
      throws OperationException, InvalidHashException {

    NavigableSet<VersionedWaveletDelta> serverDeltas =
        deserializedTransformedDeltas.tailSet(
            deserializedTransformedDeltas.floor(
                emptyDeserializedDeltaAtVersion(appliedVersion.getVersion())),
            true);

    if (serverDeltas.size() == 0) {
      LOG.warning("Got empty server set, but not sumbitting to head! " + submittedDelta);
      // Not strictly an invalid hash, but it's a related issue
      throw new InvalidHashException("Cannot submit to head");
    }

    // Confirm that the target version/hash of this delta is valid.
    if (!serverDeltas.first().version.equals(appliedVersion)) {
      LOG.warning(
          "Mismatched hashes: expected: "
              + serverDeltas.first().version
              + " got: "
              + appliedVersion);
      // Don't leak the hash to the client in the error message.
      throw new InvalidHashException("Mismatched hashes at version " + appliedVersion.getVersion());
    }

    ParticipantId clientAuthor = submittedDelta.getAuthor();
    List<WaveletOperation> clientOps = submittedDelta.getOperations();
    for (VersionedWaveletDelta d : serverDeltas) {
      // If the client delta transforms to nothing before we've traversed all the server
      // deltas, return the version at which the delta was obliterated (rather than the
      // current version) to ensure that delta submission is idempotent.
      if (clientOps.isEmpty()) {
        return new VersionedWaveletDelta(new WaveletDelta(clientAuthor, clientOps), d.version);
      }
      ParticipantId serverAuthor = d.delta.getAuthor();
      List<WaveletOperation> serverOps = d.delta.getOperations();
      if (clientAuthor.equals(serverAuthor) && clientOps.equals(serverOps)) {
        return d;
      }
      clientOps = transformOps(clientOps, clientAuthor, serverOps, serverAuthor);
    }
    return new VersionedWaveletDelta(new WaveletDelta(clientAuthor, clientOps), currentVersion);
  }
    RandomSelection select(boolean narrow, boolean mixInNotPresentItems, boolean permitReversal) {
      ThreadLocalRandom random = ThreadLocalRandom.current();
      NavigableSet<Integer> canonicalSet = this.canonical;
      BTreeSet<Integer> testAsSet = this.test;
      List<Integer> canonicalList = new ArrayList<>(canonicalSet);
      BTreeSet<Integer> testAsList = this.test;

      Assert.assertEquals(canonicalSet.size(), testAsSet.size());
      Assert.assertEquals(canonicalList.size(), testAsList.size());

      // sometimes select keys first, so we cover full range
      List<Integer> allKeys = randomKeys(canonical, mixInNotPresentItems);
      List<Integer> keys = allKeys;

      int narrowCount = random.nextInt(3);
      while (narrow && canonicalList.size() > 10 && keys.size() > 10 && narrowCount-- > 0) {
        boolean useLb = random.nextBoolean();
        boolean useUb = random.nextBoolean();
        if (!(useLb | useUb)) continue;

        // select a range smaller than the total span when we have more narrowing iterations left
        int indexRange = keys.size() / (narrowCount + 1);

        boolean lbInclusive = true;
        Integer lbKey = canonicalList.get(0);
        int lbKeyIndex = 0, lbIndex = 0;
        boolean ubInclusive = true;
        Integer ubKey = canonicalList.get(canonicalList.size() - 1);
        int ubKeyIndex = keys.size(), ubIndex = canonicalList.size();

        if (useLb) {
          lbKeyIndex = random.nextInt(0, indexRange - 1);
          Integer candidate = keys.get(lbKeyIndex);
          if (useLb = (candidate > lbKey && candidate <= ubKey)) {
            lbInclusive = random.nextBoolean();
            lbKey = keys.get(lbKeyIndex);
            lbIndex = Collections.binarySearch(canonicalList, lbKey);
            if (lbIndex >= 0 && !lbInclusive) lbIndex++;
            else if (lbIndex < 0) lbIndex = -1 - lbIndex;
          }
        }
        if (useUb) {
          ubKeyIndex =
              random.nextInt(Math.max(lbKeyIndex, keys.size() - indexRange), keys.size() - 1);
          Integer candidate = keys.get(ubKeyIndex);
          if (useUb = (candidate < ubKey && candidate >= lbKey)) {
            ubInclusive = random.nextBoolean();
            ubKey = keys.get(ubKeyIndex);
            ubIndex = Collections.binarySearch(canonicalList, ubKey);
            if (ubIndex >= 0 && ubInclusive) {
              ubIndex++;
            } else if (ubIndex < 0) ubIndex = -1 - ubIndex;
          }
        }
        if (ubIndex < lbIndex) {
          ubIndex = lbIndex;
          ubKey = lbKey;
          ubInclusive = false;
        }

        canonicalSet =
            !useLb
                ? canonicalSet.headSet(ubKey, ubInclusive)
                : !useUb
                    ? canonicalSet.tailSet(lbKey, lbInclusive)
                    : canonicalSet.subSet(lbKey, lbInclusive, ubKey, ubInclusive);
        testAsSet =
            !useLb
                ? testAsSet.headSet(ubKey, ubInclusive)
                : !useUb
                    ? testAsSet.tailSet(lbKey, lbInclusive)
                    : testAsSet.subSet(lbKey, lbInclusive, ubKey, ubInclusive);

        keys = keys.subList(lbKeyIndex, ubKeyIndex);
        canonicalList = canonicalList.subList(lbIndex, ubIndex);
        testAsList = testAsList.subList(lbIndex, ubIndex);

        Assert.assertEquals(canonicalSet.size(), testAsSet.size());
        Assert.assertEquals(canonicalList.size(), testAsList.size());
      }

      // possibly restore full set of keys, to test case where we are provided existing keys that
      // are out of bounds
      if (keys != allKeys && random.nextBoolean()) keys = allKeys;

      Comparator<Integer> comparator = naturalOrder();
      if (permitReversal && random.nextBoolean()) {
        if (allKeys != keys) keys = new ArrayList<>(keys);
        if (canonicalSet != canonical) canonicalList = new ArrayList<>(canonicalList);
        Collections.reverse(keys);
        Collections.reverse(canonicalList);
        testAsList = testAsList.descendingSet();

        canonicalSet = canonicalSet.descendingSet();
        testAsSet = testAsSet.descendingSet();
        comparator = reverseOrder();
      }

      Assert.assertEquals(canonicalSet.size(), testAsSet.size());
      Assert.assertEquals(canonicalList.size(), testAsList.size());
      if (!canonicalSet.isEmpty()) {
        Assert.assertEquals(canonicalSet.first(), canonicalList.get(0));
        Assert.assertEquals(canonicalSet.last(), canonicalList.get(canonicalList.size() - 1));
        Assert.assertEquals(canonicalSet.first(), testAsSet.first());
        Assert.assertEquals(canonicalSet.last(), testAsSet.last());
        Assert.assertEquals(canonicalSet.first(), testAsList.get(0));
        Assert.assertEquals(canonicalSet.last(), testAsList.get(testAsList.size() - 1));
      }

      return new RandomSelection(
          keys, canonicalSet, testAsSet, canonicalList, testAsList, comparator);
    }