/** Initializes future. */
  @SuppressWarnings({"unchecked"})
  void finish() {
    if (tx.onePhaseCommit()) {
      // No need to send messages as transaction was already committed on remote node.
      markInitialized();

      return;
    }

    if (mappings != null) {
      finish(mappings.values());

      markInitialized();

      if (!isSync()) {
        boolean complete = true;

        for (GridFuture<?> f : pending())
          // Mini-future in non-sync mode gets done when message gets sent.
          if (isMini(f) && !f.isDone()) complete = false;

        if (complete) onComplete();
      }
    } else {
      assert !commit;

      try {
        tx.rollback();
      } catch (GridException e) {
        U.error(log, "Failed to rollback empty transaction: " + tx, e);
      }

      markInitialized();
    }
  }
Example #2
0
  /**
   * @param mapping Mappings.
   * @param key Key to map.
   * @param topVer Topology version.
   * @return Near lock mapping.
   * @throws GridException If mapping for key failed.
   */
  private GridNearLockMapping<K, V> map(
      K key, @Nullable GridNearLockMapping<K, V> mapping, long topVer) throws GridException {
    assert mapping == null || mapping.node() != null;

    GridNode primary = cctx.affinity().primary(key, topVer);

    if (cctx.discovery().node(primary.id()) == null)
      // If primary node left the grid before lock acquisition, fail the whole future.
      throw newTopologyException(null, primary.id());

    if (inTx() && tx.groupLock() && !primary.isLocal())
      throw new GridException(
          "Failed to start group lock transaction (local node is not primary for "
              + " key) [key="
              + key
              + ", primaryNodeId="
              + primary.id()
              + ']');

    if (mapping == null || !primary.id().equals(mapping.node().id()))
      mapping = new GridNearLockMapping<>(primary, key);
    else mapping.addKey(key);

    return mapping;
  }
  /** @param e Error. */
  void onError(Throwable e) {
    tx.commitError(e);

    if (err.compareAndSet(null, e)) {
      boolean marked = tx.setRollbackOnly();

      if (e instanceof GridCacheTxRollbackException) {
        if (marked) {
          try {
            tx.rollback();
          } catch (GridException ex) {
            U.error(log, "Failed to automatically rollback transaction: " + tx, ex);
          }
        }
      } else if (tx.implicit()
          && tx.isSystemInvalidate()) { // Finish implicit transaction on heuristic error.
        try {
          tx.close();
        } catch (GridException ex) {
          U.error(log, "Failed to invalidate transaction: " + tx, ex);
        }
      }

      onComplete();
    }
  }
Example #4
0
  /**
   * @param cctx Registry.
   * @param keys Keys to lock.
   * @param tx Transaction.
   * @param read Read flag.
   * @param retval Flag to return value or not.
   * @param timeout Lock acquisition timeout.
   * @param filter Filter.
   */
  public GridNearLockFuture(
      GridCacheContext<K, V> cctx,
      Collection<? extends K> keys,
      @Nullable GridNearTxLocal<K, V> tx,
      boolean read,
      boolean retval,
      long timeout,
      GridPredicate<GridCacheEntry<K, V>>[] filter) {
    super(cctx.kernalContext(), CU.boolReducer());
    assert cctx != null;
    assert keys != null;

    this.cctx = cctx;
    this.keys = keys;
    this.tx = tx;
    this.read = read;
    this.retval = retval;
    this.timeout = timeout;
    this.filter = filter;

    threadId = tx == null ? Thread.currentThread().getId() : tx.threadId();

    lockVer = tx != null ? tx.xidVersion() : cctx.versions().next();

    futId = GridUuid.randomUuid();

    entries = new ArrayList<>(keys.size());

    log = U.logger(ctx, logRef, GridNearLockFuture.class);

    if (timeout > 0) {
      timeoutObj = new LockTimeoutObject();

      cctx.time().addTimeoutObject(timeoutObj);
    }

    valMap = new ConcurrentHashMap8<>(keys.size(), 1f);
  }
Example #5
0
  /**
   * Acquires topology future and checks it completeness under the read lock. If it is not complete,
   * will asynchronously wait for it's completeness and then try again.
   */
  void mapOnTopology() {
    // We must acquire topology snapshot from the topology version future.
    try {
      cctx.topology().readLock();

      try {
        GridDhtTopologyFuture fut = cctx.topologyVersionFuture();

        if (fut.isDone()) {
          GridDiscoveryTopologySnapshot snapshot = fut.topologySnapshot();

          if (tx != null) {
            tx.topologyVersion(snapshot.topologyVersion());
            tx.topologySnapshot(snapshot);
          }

          topSnapshot.compareAndSet(null, snapshot);

          map(keys);

          markInitialized();
        } else {
          fut.listenAsync(
              new CI1<GridFuture<Long>>() {
                @Override
                public void apply(GridFuture<Long> t) {
                  mapOnTopology();
                }
              });
        }
      } finally {
        cctx.topology().readUnlock();
      }
    } catch (GridException e) {
      onDone(e);
    }
  }
  /**
   * @param cctx Context.
   * @param tx Transaction.
   * @param commit Commit flag.
   */
  public GridNearTxFinishFuture(
      GridCacheContext<K, V> cctx, GridNearTxLocal<K, V> tx, boolean commit) {
    super(cctx.kernalContext(), F.<GridCacheTx>identityReducer(tx));

    this.cctx = cctx;
    this.tx = tx;
    this.commit = commit;

    ignoreInterrupts(true);

    mappings = tx.mappings();

    futId = GridUuid.randomUuid();

    log = U.logger(ctx, logRef, GridNearTxFinishFuture.class);
  }
Example #7
0
  /**
   * Undoes all locks.
   *
   * @param dist If {@code true}, then remove locks from remote nodes as well.
   */
  private void undoLocks(boolean dist) {
    // Transactions will undo during rollback.
    if (dist && tx == null) cctx.nearTx().removeLocks(lockVer, keys);
    else {
      if (tx != null) {
        if (tx.setRollbackOnly()) {
          if (log.isDebugEnabled())
            log.debug(
                "Marked transaction as rollback only because locks could not be acquired: " + tx);
        } else if (log.isDebugEnabled())
          log.debug(
              "Transaction was not marked rollback-only while locks were not acquired: " + tx);
      }

      for (GridCacheEntryEx<K, V> e : entriesCopy()) {
        try {
          e.removeLock(lockVer);
        } catch (GridCacheEntryRemovedException ignored) {
          while (true) {
            try {
              e = cctx.cache().peekEx(e.key());

              if (e != null) e.removeLock(lockVer);

              break;
            } catch (GridCacheEntryRemovedException ignore) {
              if (log.isDebugEnabled())
                log.debug(
                    "Attempted to remove lock on removed entry (will retry) [ver="
                        + lockVer
                        + ", entry="
                        + e
                        + ']');
            }
          }
        }
      }
    }

    cctx.mvcc().recheckPendingLocks();
  }
Example #8
0
  /**
   * Adds entry to future.
   *
   * @param topVer Topology version.
   * @param entry Entry to add.
   * @param dhtNodeId DHT node ID.
   * @return Lock candidate.
   * @throws GridCacheEntryRemovedException If entry was removed.
   */
  @Nullable
  private GridCacheMvccCandidate<K> addEntry(
      long topVer, GridNearCacheEntry<K, V> entry, UUID dhtNodeId)
      throws GridCacheEntryRemovedException {
    // Check if lock acquisition is timed out.
    if (timedOut) return null;

    // Add local lock first, as it may throw GridCacheEntryRemovedException.
    GridCacheMvccCandidate<K> c =
        entry.addNearLocal(
            dhtNodeId, threadId, lockVer, timeout, !inTx(), inTx(), implicitSingleTx());

    if (inTx()) {
      GridCacheTxEntry<K, V> txEntry = tx.entry(entry.key());

      txEntry.cached(entry, txEntry.keyBytes());
    }

    if (c != null) c.topologyVersion(topVer);

    synchronized (mux) {
      entries.add(entry);
    }

    if (c == null && timeout < 0) {
      if (log.isDebugEnabled()) log.debug("Failed to acquire lock with negative timeout: " + entry);

      onFailed(false);

      return null;
    }

    // Double check if lock acquisition has already timed out.
    if (timedOut) {
      entry.removeLock(lockVer);

      return null;
    }

    return c;
  }
Example #9
0
  /**
   * Basically, future mapping consists from two parts. First, we must determine the topology
   * version this future will map on. Locking is performed within a user transaction, we must
   * continue to map keys on the same topology version as it started. If topology version is
   * undefined, we get current topology future and wait until it completes so the topology is ready
   * to use.
   *
   * <p>During the second part we map keys to primary nodes using topology snapshot we obtained
   * during the first part. Note that if primary node leaves grid, the future will fail and
   * transaction will be rolled back.
   */
  void map() {
    // Obtain the topology version to use.
    GridDiscoveryTopologySnapshot snapshot =
        tx != null
            ? tx.topologySnapshot()
            : cctx.mvcc().lastExplicitLockTopologySnapshot(Thread.currentThread().getId());

    if (snapshot != null) {
      // Continue mapping on the same topology version as it was before.
      topSnapshot.compareAndSet(null, snapshot);

      map(keys);

      markInitialized();

      return;
    }

    // Must get topology snapshot and map on that version.
    mapOnTopology();
  }
Example #10
0
 /** @return {@code true} if related transaction is implicit. */
 private boolean implicitTx() {
   return tx != null && tx.implicit();
 }
Example #11
0
 /** @return Transaction isolation or {@code null} if no transaction. */
 @Nullable
 private GridCacheTxIsolation isolation() {
   return tx == null ? null : tx.isolation();
 }
Example #12
0
 /** @return {@code True} if rollback is synchronous. */
 private boolean syncRollback() {
   return tx != null && tx.syncRollback();
 }
Example #13
0
  /**
   * Maps keys to nodes. Note that we can not simply group keys by nodes and send lock request as
   * such approach does not preserve order of lock acquisition. Instead, keys are split in
   * continuous groups belonging to one primary node and locks for these groups are acquired
   * sequentially.
   *
   * @param keys Keys.
   */
  private void map(Iterable<? extends K> keys) {
    try {
      GridDiscoveryTopologySnapshot snapshot = topSnapshot.get();

      assert snapshot != null;

      long topVer = snapshot.topologyVersion();

      assert topVer > 0;

      if (CU.affinityNodes(cctx, topVer).isEmpty()) {
        onDone(
            new GridTopologyException(
                "Failed to map keys for near-only cache (all "
                    + "partition nodes left the grid)."));

        return;
      }

      ConcurrentLinkedDeque8<GridNearLockMapping<K, V>> mappings = new ConcurrentLinkedDeque8<>();

      // Assign keys to primary nodes.
      GridNearLockMapping<K, V> map = null;

      for (K key : keys) {
        GridNearLockMapping<K, V> updated = map(key, map, topVer);

        // If new mapping was created, add to collection.
        if (updated != map) mappings.add(updated);

        map = updated;
      }

      if (isDone()) {
        if (log.isDebugEnabled()) log.debug("Abandoning (re)map because future is done: " + this);

        return;
      }

      if (log.isDebugEnabled())
        log.debug("Starting (re)map for mappings [mappings=" + mappings + ", fut=" + this + ']');

      // Create mini futures.
      for (Iterator<GridNearLockMapping<K, V>> iter = mappings.iterator(); iter.hasNext(); ) {
        GridNearLockMapping<K, V> mapping = iter.next();

        GridNode node = mapping.node();
        Collection<K> mappedKeys = mapping.mappedKeys();

        assert !mappedKeys.isEmpty();

        GridNearLockRequest<K, V> req = null;

        Collection<K> distributedKeys = new ArrayList<>(mappedKeys.size());

        boolean explicit = false;

        for (K key : mappedKeys) {
          while (true) {
            GridNearCacheEntry<K, V> entry = null;

            try {
              entry = cctx.near().entryExx(key, topVer);

              if (!cctx.isAll(entry.wrap(false), filter)) {
                if (log.isDebugEnabled())
                  log.debug("Entry being locked did not pass filter (will not lock): " + entry);

                onComplete(false, false);

                return;
              }

              // Removed exception may be thrown here.
              GridCacheMvccCandidate<K> cand = addEntry(topVer, entry, node.id());

              if (isDone()) {
                if (log.isDebugEnabled())
                  log.debug(
                      "Abandoning (re)map because future is done after addEntry attempt "
                          + "[fut="
                          + this
                          + ", entry="
                          + entry
                          + ']');

                return;
              }

              if (cand != null) {
                if (tx == null && !cand.reentry())
                  cctx.mvcc().addExplicitLock(threadId, cand, snapshot);

                GridTuple3<GridCacheVersion, V, byte[]> val = entry.versionedValue();

                if (val == null) {
                  GridDhtCacheEntry<K, V> dhtEntry = dht().peekExx(key);

                  try {
                    if (dhtEntry != null) val = dhtEntry.versionedValue(topVer);
                  } catch (GridCacheEntryRemovedException ignored) {
                    assert dhtEntry.obsolete()
                        : " Got removed exception for non-obsolete entry: " + dhtEntry;

                    if (log.isDebugEnabled())
                      log.debug(
                          "Got removed exception for DHT entry in map (will ignore): " + dhtEntry);
                  }
                }

                GridCacheVersion dhtVer = null;

                if (val != null) {
                  dhtVer = val.get1();

                  valMap.put(key, val);
                }

                if (!cand.reentry()) {
                  if (req == null) {
                    req =
                        new GridNearLockRequest<>(
                            topVer,
                            cctx.nodeId(),
                            threadId,
                            futId,
                            lockVer,
                            inTx(),
                            implicitTx(),
                            implicitSingleTx(),
                            read,
                            isolation(),
                            isInvalidate(),
                            timeout,
                            syncCommit(),
                            syncRollback(),
                            mappedKeys.size(),
                            inTx() ? tx.size() : mappedKeys.size(),
                            inTx() ? tx.groupLockKey() : null,
                            inTx() && tx.partitionLock(),
                            inTx() ? tx.subjectId() : null);

                    mapping.request(req);
                  }

                  distributedKeys.add(key);

                  GridCacheTxEntry<K, V> writeEntry = tx != null ? tx.writeMap().get(key) : null;

                  if (tx != null) tx.addKeyMapping(key, mapping.node());

                  req.addKeyBytes(
                      key,
                      node.isLocal() ? null : entry.getOrMarshalKeyBytes(),
                      retval && dhtVer == null,
                      dhtVer, // Include DHT version to match remote DHT entry.
                      writeEntry,
                      inTx() ? tx.entry(key).drVersion() : null,
                      cctx);

                  // Clear transfer required flag since we are sending message.
                  if (writeEntry != null) writeEntry.transferRequired(false);
                }

                if (cand.reentry())
                  explicit = tx != null && !entry.hasLockCandidate(tx.xidVersion());
              } else
                // Ignore reentries within transactions.
                explicit = tx != null && !entry.hasLockCandidate(tx.xidVersion());

              if (explicit) tx.addKeyMapping(key, mapping.node());

              break;
            } catch (GridCacheEntryRemovedException ignored) {
              assert entry.obsolete() : "Got removed exception on non-obsolete entry: " + entry;

              if (log.isDebugEnabled())
                log.debug("Got removed entry in lockAsync(..) method (will retry): " + entry);
            }
          }

          // Mark mapping explicit lock flag.
          if (explicit) {
            boolean marked = tx != null && tx.markExplicit(node.id());

            assert tx == null || marked;
          }
        }

        if (!distributedKeys.isEmpty()) mapping.distributedKeys(distributedKeys);
        else {
          assert mapping.request() == null;

          iter.remove();
        }
      }

      cctx.mvcc().recheckPendingLocks();

      proceedMapping(mappings);
    } catch (GridException ex) {
      onError(ex);
    }
  }
Example #14
0
 /** @return {@code True} if implicit-single-tx flag is set. */
 private boolean implicitSingleTx() {
   return tx != null && tx.implicitSingle();
 }
  /** @param m Mapping. */
  private void finish(GridDistributedTxMapping<K, V> m) {
    GridNode n = m.node();

    assert !m.empty();

    GridNearTxFinishRequest<K, V> req =
        new GridNearTxFinishRequest<>(
            futId,
            tx.xidVersion(),
            tx.threadId(),
            commit,
            tx.isInvalidate(),
            m.explicitLock(),
            tx.topologyVersion(),
            null,
            null,
            null,
            tx.size(),
            commit && tx.pessimistic() ? m.writes() : null,
            commit && tx.pessimistic() ? tx.writeEntries() : null,
            commit ? tx.syncCommit() : tx.syncRollback(),
            tx.subjectId(),
            tx.taskNameHash());

    // If this is the primary node for the keys.
    if (n.isLocal()) {
      req.miniId(GridUuid.randomUuid());

      if (CU.DHT_ENABLED) {
        GridFuture<GridCacheTx> fut =
            commit ? dht().commitTx(n.id(), req) : dht().rollbackTx(n.id(), req);

        // Add new future.
        add(fut);
      } else
        // Add done future for testing.
        add(new GridFinishedFuture<GridCacheTx>(ctx));
    } else {
      MiniFuture fut = new MiniFuture(m);

      req.miniId(fut.futureId());

      add(fut); // Append new future.

      if (tx.pessimistic()) cctx.tm().beforeFinishRemote(n.id(), tx.threadId());

      try {
        cctx.io().send(n, req);

        // If we don't wait for result, then mark future as done.
        if (!isSync() && !m.explicitLock()) fut.onDone();
      } catch (GridTopologyException e) {
        // Remove previous mapping.
        mappings.remove(m.node().id());

        fut.onResult(e);
      } catch (GridException e) {
        // Fail the whole thing.
        fut.onResult(e);
      }
    }
  }
Example #16
0
 /** @return {@code True} if transaction is not {@code null} and has invalidate flag set. */
 private boolean isInvalidate() {
   return tx != null && tx.isInvalidate();
 }
Example #17
0
 /** @return {@code True} if commit is synchronous. */
 private boolean syncCommit() {
   return tx != null && tx.syncCommit();
 }
Example #18
0
  /**
   * Gets next near lock mapping and either acquires dht locks locally or sends near lock request to
   * remote primary node.
   *
   * @param mappings Queue of mappings.
   * @throws GridException If mapping can not be completed.
   */
  private void proceedMapping(final ConcurrentLinkedDeque8<GridNearLockMapping<K, V>> mappings)
      throws GridException {
    GridNearLockMapping<K, V> map = mappings.poll();

    // If there are no more mappings to process, complete the future.
    if (map == null) return;

    final GridNearLockRequest<K, V> req = map.request();
    final Collection<K> mappedKeys = map.distributedKeys();
    final GridNode node = map.node();

    if (filter != null && filter.length != 0) req.filter(filter, cctx);

    if (node.isLocal()) {
      req.miniId(GridUuid.randomUuid());

      if (log.isDebugEnabled()) log.debug("Before locally locking near request: " + req);

      GridFuture<GridNearLockResponse<K, V>> fut;

      if (CU.DHT_ENABLED) fut = dht().lockAllAsync(cctx.localNode(), req, filter);
      else {
        // Create dummy values for testing.
        GridNearLockResponse<K, V> res =
            new GridNearLockResponse<>(lockVer, futId, null, false, 1, null);

        res.addValueBytes(null, null, true, lockVer, lockVer, cctx);

        fut = new GridFinishedFuture<>(ctx, res);
      }

      // Add new future.
      add(
          new GridEmbeddedFuture<>(
              cctx.kernalContext(),
              fut,
              new C2<GridNearLockResponse<K, V>, Exception, Boolean>() {
                @Override
                public Boolean apply(GridNearLockResponse<K, V> res, Exception e) {
                  if (CU.isLockTimeoutOrCancelled(e)
                      || (res != null && CU.isLockTimeoutOrCancelled(res.error()))) return false;

                  if (e != null) {
                    onError(e);

                    return false;
                  }

                  if (res == null) {
                    onError(new GridException("Lock response is null for future: " + this));

                    return false;
                  }

                  if (res.error() != null) {
                    onError(res.error());

                    return false;
                  }

                  if (log.isDebugEnabled())
                    log.debug(
                        "Acquired lock for local DHT mapping [locId="
                            + cctx.nodeId()
                            + ", mappedKeys="
                            + mappedKeys
                            + ", fut="
                            + GridNearLockFuture.this
                            + ']');

                  try {
                    int i = 0;

                    for (K k : mappedKeys) {
                      while (true) {
                        GridNearCacheEntry<K, V> entry =
                            cctx.near().entryExx(k, req.topologyVersion());

                        try {
                          GridTuple3<GridCacheVersion, V, byte[]> oldValTup =
                              valMap.get(entry.key());

                          boolean hasBytes = entry.hasValue();
                          V oldVal = entry.rawGet();
                          V newVal = res.value(i);
                          byte[] newBytes = res.valueBytes(i);

                          GridCacheVersion dhtVer = res.dhtVersion(i);
                          GridCacheVersion mappedVer = res.mappedVersion(i);

                          // On local node don't record twice if DHT cache already recorded.
                          boolean record =
                              retval && oldValTup != null && oldValTup.get1().equals(dhtVer);

                          if (newVal == null) {
                            if (oldValTup != null) {
                              if (oldValTup.get1().equals(dhtVer)) {
                                newVal = oldValTup.get2();

                                newBytes = oldValTup.get3();
                              }

                              oldVal = oldValTup.get2();
                            }
                          }

                          // Lock is held at this point, so we can set the
                          // returned value if any.
                          entry.resetFromPrimary(newVal, newBytes, lockVer, dhtVer, node.id());

                          entry.readyNearLock(
                              lockVer,
                              mappedVer,
                              res.committedVersions(),
                              res.rolledbackVersions(),
                              res.pending());

                          if (inTx() && implicitTx() && tx.onePhaseCommit()) {
                            boolean pass = res.filterResult(i);

                            tx.entry(k).filters(pass ? CU.<K, V>empty() : CU.<K, V>alwaysFalse());
                          }

                          if (record) {
                            if (cctx.events().isRecordable(EVT_CACHE_OBJECT_READ))
                              cctx.events()
                                  .addEvent(
                                      entry.partition(),
                                      entry.key(),
                                      tx,
                                      null,
                                      EVT_CACHE_OBJECT_READ,
                                      newVal,
                                      newVal != null,
                                      oldVal,
                                      hasBytes,
                                      CU.subjectId(tx, cctx));

                            cctx.cache().metrics0().onRead(oldVal != null);
                          }

                          if (log.isDebugEnabled())
                            log.debug(
                                "Processed response for entry [res="
                                    + res
                                    + ", entry="
                                    + entry
                                    + ']');

                          break; // Inner while loop.
                        } catch (GridCacheEntryRemovedException ignored) {
                          if (log.isDebugEnabled())
                            log.debug(
                                "Failed to add candidates because entry was "
                                    + "removed (will renew).");

                          // Replace old entry with new one.
                          entries.set(
                              i,
                              (GridDistributedCacheEntry<K, V>) cctx.cache().entryEx(entry.key()));
                        }
                      }

                      i++; // Increment outside of while loop.
                    }

                    // Proceed and add new future (if any) before completing embedded future.
                    proceedMapping(mappings);
                  } catch (GridException ex) {
                    onError(ex);

                    return false;
                  }

                  return true;
                }
              }));
    } else {
      final MiniFuture fut = new MiniFuture(node, mappedKeys, mappings);

      req.miniId(fut.futureId());

      add(fut); // Append new future.

      GridFuture<?> txSync = null;

      if (inTx()) txSync = cctx.tm().awaitFinishAckAsync(node.id(), tx.threadId());

      if (txSync == null || txSync.isDone()) {
        try {
          if (log.isDebugEnabled())
            log.debug("Sending near lock request [node=" + node.id() + ", req=" + req + ']');

          cctx.io().send(node, req);
        } catch (GridTopologyException ex) {
          assert fut != null;

          fut.onResult(ex);
        }
      } else {
        txSync.listenAsync(
            new CI1<GridFuture<?>>() {
              @Override
              public void apply(GridFuture<?> t) {
                try {
                  if (log.isDebugEnabled())
                    log.debug(
                        "Sending near lock request [node=" + node.id() + ", req=" + req + ']');

                  cctx.io().send(node, req);
                } catch (GridTopologyException ex) {
                  assert fut != null;

                  fut.onResult(ex);
                } catch (GridException e) {
                  onError(e);
                }
              }
            });
      }
    }
  }
 /** {@inheritDoc} */
 @Override
 public GridCacheVersion version() {
   return tx.xidVersion();
 }