@Test public void testTwoDraws() throws Exception { // Test initialisation /* * find a seed for which the draw differs: we loop until the * first index drawn (Random(seed).nextInt(SilanisLottery.MAX_BALL)) * is different from the first index drawn for * Random(seed + 1).SilanisLottery.MAX_BALL */ long seed; do { seed = System.currentTimeMillis(); } while (new Random(seed).nextInt(SilanisLottery.MAX_BALL) == new Random(seed + 1).nextInt(SilanisLottery.MAX_BALL)); this.drawableInteger = new DrawableInteger(new Random(seed)); final List<Integer> draws = new ArrayList<>(); this.fillDraws(draws); final List<Integer> secondDraws = new ArrayList<>(); this.drawableInteger = new DrawableInteger(new Random(seed + 1)); this.fillDraws(secondDraws); assertThat(secondDraws).as("The sequence of draws is supposed").isNotEqualTo(draws); }
@Test public void testTwoDrawsInitializedWithTheSameSeed() throws Exception { final long seed = System.currentTimeMillis(); this.drawableInteger = new DrawableInteger(new Random(seed)); final List<Integer> draws = new ArrayList<>(); this.fillDraws(draws); final List<Integer> secondDraws = new ArrayList<>(); this.drawableInteger = new DrawableInteger(new Random(seed)); this.fillDraws(secondDraws); // secondDraws will be strictly equal to this.drawableInteger assertThat(secondDraws).isEqualTo(draws); }
private void testGetOldestNewestCSNs(final int max, final int counterWindow) throws Exception { String tn = "testDBCount(" + max + "," + counterWindow + ")"; debugInfo(tn, "Starting test"); File testRoot = null; ReplicationServer replicationServer = null; ReplicationDbEnv dbEnv = null; JEReplicaDB replicaDB = null; try { TestCaseUtils.startServer(); replicationServer = configureReplicationServer(100000, 10); testRoot = createCleanDir(); dbEnv = new ReplicationDbEnv(testRoot.getPath(), replicationServer); replicaDB = new JEReplicaDB(1, TEST_ROOT_DN, replicationServer, dbEnv); replicaDB.setCounterRecordWindowSize(counterWindow); // Populate the db with 'max' msg int mySeqnum = 1; CSN csns[] = new CSN[2 * (max + 1)]; long now = System.currentTimeMillis(); for (int i = 1; i <= max; i++) { csns[i] = new CSN(now + i, mySeqnum, 1); replicaDB.add(new DeleteMsg(TEST_ROOT_DN, csns[i], "uid")); mySeqnum += 2; } assertEquals(replicaDB.getOldestCSN(), csns[1], "Wrong oldest CSN"); assertEquals(replicaDB.getNewestCSN(), csns[max], "Wrong newest CSN"); // Now we want to test that after closing and reopening the db, the // counting algo is well reinitialized and when new messages are added // the new counter are correctly generated. debugInfo(tn, "SHUTDOWN replicaDB and recreate"); replicaDB.shutdown(); replicaDB = new JEReplicaDB(1, TEST_ROOT_DN, replicationServer, dbEnv); replicaDB.setCounterRecordWindowSize(counterWindow); assertEquals(replicaDB.getOldestCSN(), csns[1], "Wrong oldest CSN"); assertEquals(replicaDB.getNewestCSN(), csns[max], "Wrong newest CSN"); // Populate the db with 'max' msg for (int i = max + 1; i <= 2 * max; i++) { csns[i] = new CSN(now + i, mySeqnum, 1); replicaDB.add(new DeleteMsg(TEST_ROOT_DN, csns[i], "uid")); mySeqnum += 2; } assertEquals(replicaDB.getOldestCSN(), csns[1], "Wrong oldest CSN"); assertEquals(replicaDB.getNewestCSN(), csns[2 * max], "Wrong newest CSN"); replicaDB.purgeUpTo(new CSN(Long.MAX_VALUE, 0, 0)); String testcase = "AFTER PURGE (oldest, newest)="; debugInfo(tn, testcase + replicaDB.getOldestCSN() + replicaDB.getNewestCSN()); assertEquals(replicaDB.getNewestCSN(), csns[2 * max], "Newest="); // Clear ... debugInfo(tn, "clear:"); replicaDB.clear(); // Check the db is cleared. assertEquals(null, replicaDB.getOldestCSN()); assertEquals(null, replicaDB.getNewestCSN()); debugInfo(tn, "Success"); } finally { shutdown(replicaDB); if (dbEnv != null) { dbEnv.shutdown(); } remove(replicationServer); TestCaseUtils.deleteDirectory(testRoot); } }
@DataProvider Object[][] cursorData() { // create 7 csns final CSN[] sevenCsns = generateCSNs(1, System.currentTimeMillis(), 7); CSN beforeCsn = sevenCsns[0]; CSN middleCsn = sevenCsns[3]; // will be between csns[1] and csns[2] CSN afterCsn = sevenCsns[6]; // but use only 4 of them for update msg // beforeCsn, middleCsn and afterCsn are not used // in order to test cursor generation from a key not present in the log (before, in the middle, // after) final List<CSN> usedCsns = new ArrayList<CSN>(Arrays.asList(sevenCsns)); usedCsns.remove(beforeCsn); usedCsns.remove(middleCsn); usedCsns.remove(afterCsn); final CSN[] csns = usedCsns.toArray(new CSN[4]); return new Object[][] { // equal matching {csns, beforeCsn, EQUAL_TO_KEY, ON_MATCHING_KEY, -1, -1}, {csns, csns[0], EQUAL_TO_KEY, ON_MATCHING_KEY, 0, 3}, {csns, csns[1], EQUAL_TO_KEY, ON_MATCHING_KEY, 1, 3}, {csns, middleCsn, EQUAL_TO_KEY, ON_MATCHING_KEY, -1, -1}, {csns, csns[2], EQUAL_TO_KEY, ON_MATCHING_KEY, 2, 3}, {csns, csns[3], EQUAL_TO_KEY, ON_MATCHING_KEY, 3, 3}, {csns, afterCsn, EQUAL_TO_KEY, ON_MATCHING_KEY, -1, -1}, {csns, beforeCsn, EQUAL_TO_KEY, AFTER_MATCHING_KEY, -1, -1}, {csns, csns[0], EQUAL_TO_KEY, AFTER_MATCHING_KEY, 1, 3}, {csns, csns[1], EQUAL_TO_KEY, AFTER_MATCHING_KEY, 2, 3}, {csns, middleCsn, EQUAL_TO_KEY, AFTER_MATCHING_KEY, -1, -1}, {csns, csns[2], EQUAL_TO_KEY, AFTER_MATCHING_KEY, 3, 3}, {csns, csns[3], EQUAL_TO_KEY, AFTER_MATCHING_KEY, -1, -1}, {csns, afterCsn, EQUAL_TO_KEY, AFTER_MATCHING_KEY, -1, -1}, // less than or equal matching {csns, beforeCsn, LESS_THAN_OR_EQUAL_TO_KEY, ON_MATCHING_KEY, -1, -1}, {csns, csns[0], LESS_THAN_OR_EQUAL_TO_KEY, ON_MATCHING_KEY, 0, 3}, {csns, csns[1], LESS_THAN_OR_EQUAL_TO_KEY, ON_MATCHING_KEY, 1, 3}, {csns, middleCsn, LESS_THAN_OR_EQUAL_TO_KEY, ON_MATCHING_KEY, 1, 3}, {csns, csns[2], LESS_THAN_OR_EQUAL_TO_KEY, ON_MATCHING_KEY, 2, 3}, {csns, csns[3], LESS_THAN_OR_EQUAL_TO_KEY, ON_MATCHING_KEY, 3, 3}, {csns, afterCsn, LESS_THAN_OR_EQUAL_TO_KEY, ON_MATCHING_KEY, 3, 3}, {csns, beforeCsn, LESS_THAN_OR_EQUAL_TO_KEY, AFTER_MATCHING_KEY, -1, -1}, {csns, csns[0], LESS_THAN_OR_EQUAL_TO_KEY, AFTER_MATCHING_KEY, 1, 3}, {csns, csns[1], LESS_THAN_OR_EQUAL_TO_KEY, AFTER_MATCHING_KEY, 2, 3}, {csns, middleCsn, LESS_THAN_OR_EQUAL_TO_KEY, AFTER_MATCHING_KEY, 2, 3}, {csns, csns[2], LESS_THAN_OR_EQUAL_TO_KEY, AFTER_MATCHING_KEY, 3, 3}, {csns, csns[3], LESS_THAN_OR_EQUAL_TO_KEY, AFTER_MATCHING_KEY, -1, -1}, {csns, afterCsn, LESS_THAN_OR_EQUAL_TO_KEY, AFTER_MATCHING_KEY, -1, -1}, // greater than or equal matching {csns, beforeCsn, GREATER_THAN_OR_EQUAL_TO_KEY, ON_MATCHING_KEY, 0, 3}, {csns, csns[0], GREATER_THAN_OR_EQUAL_TO_KEY, ON_MATCHING_KEY, 0, 3}, {csns, csns[1], GREATER_THAN_OR_EQUAL_TO_KEY, ON_MATCHING_KEY, 1, 3}, {csns, middleCsn, GREATER_THAN_OR_EQUAL_TO_KEY, ON_MATCHING_KEY, 2, 3}, {csns, csns[2], GREATER_THAN_OR_EQUAL_TO_KEY, ON_MATCHING_KEY, 2, 3}, {csns, csns[3], GREATER_THAN_OR_EQUAL_TO_KEY, ON_MATCHING_KEY, 3, 3}, {csns, afterCsn, GREATER_THAN_OR_EQUAL_TO_KEY, ON_MATCHING_KEY, -1, -1}, {csns, beforeCsn, GREATER_THAN_OR_EQUAL_TO_KEY, AFTER_MATCHING_KEY, 0, 3}, {csns, csns[0], GREATER_THAN_OR_EQUAL_TO_KEY, AFTER_MATCHING_KEY, 1, 3}, {csns, csns[1], GREATER_THAN_OR_EQUAL_TO_KEY, AFTER_MATCHING_KEY, 2, 3}, {csns, middleCsn, GREATER_THAN_OR_EQUAL_TO_KEY, AFTER_MATCHING_KEY, 2, 3}, {csns, csns[2], GREATER_THAN_OR_EQUAL_TO_KEY, AFTER_MATCHING_KEY, 3, 3}, {csns, csns[3], GREATER_THAN_OR_EQUAL_TO_KEY, AFTER_MATCHING_KEY, -1, -1}, {csns, afterCsn, GREATER_THAN_OR_EQUAL_TO_KEY, AFTER_MATCHING_KEY, -1, -1}, {null, null, null, null, -1, -1} // stop line }; }