public static void dpUpdatesReorderRightMemory(BetaMemory bm, RightTupleSets srcRightTuples) { RightTupleMemory rtm = bm.getRightTupleMemory(); for (RightTuple rightTuple = srcRightTuples.getUpdateFirst(); rightTuple != null; ) { RightTuple next = rightTuple.getStagedNext(); if (rightTuple.getMemory() != null) { rightTuple.setTempRightTupleMemory(rightTuple.getMemory()); rtm.remove(rightTuple); } rightTuple = next; } for (RightTuple rightTuple = srcRightTuples.getUpdateFirst(); rightTuple != null; ) { RightTuple next = rightTuple.getStagedNext(); if (rightTuple.getTempRightTupleMemory() != null) { rtm.add(rightTuple); for (LeftTuple childLeftTuple = rightTuple.getFirstChild(); childLeftTuple != null; ) { LeftTuple childNext = childLeftTuple.getRightParentNext(); childLeftTuple.reAddLeft(); childLeftTuple = childNext; } } rightTuple = next; } }
public static void findLeftTupleBlocker( BetaNode betaNode, RightTupleMemory rtm, ContextEntry[] contextEntry, BetaConstraints constraints, LeftTuple leftTuple, FastIterator it, PropagationContext context, boolean useLeftMemory) { // This method will also remove rightTuples that are from subnetwork where no leftmemory use // used for (RightTuple rightTuple = betaNode.getFirstRightTuple(leftTuple, rtm, null, it); rightTuple != null; ) { RightTuple nextRight = (RightTuple) it.next(rightTuple); if (constraints.isAllowedCachedLeft(contextEntry, rightTuple.getFactHandle())) { leftTuple.setBlocker(rightTuple); if (useLeftMemory) { rightTuple.addBlocked(leftTuple); break; } else if (betaNode.isRightInputIsRiaNode()) { // If we aren't using leftMemory and the right input is a RIAN, then we must iterate and // find all subetwork right tuples and remove them // so we don't break rtm.remove(rightTuple); } else { break; } } rightTuple = nextRight; } }
public void doRightDeletes( NotNode notNode, LeftTupleSink sink, BetaMemory bm, InternalWorkingMemory wm, RightTupleSets srcRightTuples, LeftTupleSets trgLeftTuples) { LeftTupleMemory ltm = bm.getLeftTupleMemory(); RightTupleMemory rtm = bm.getRightTupleMemory(); ContextEntry[] contextEntry = bm.getContext(); BetaConstraints constraints = notNode.getRawConstraints(); for (RightTuple rightTuple = srcRightTuples.getDeleteFirst(); rightTuple != null; ) { RightTuple next = rightTuple.getStagedNext(); FastIterator it = notNode.getRightIterator(rtm); // assign now, so we can remove from memory before doing any possible propagations boolean useComparisonIndex = rtm.getIndexType().isComparison(); RightTuple rootBlocker = useComparisonIndex ? null : (RightTuple) it.next(rightTuple); if (rightTuple.getMemory() != null) { // it may have been staged and never actually added rtm.remove(rightTuple); } if (rightTuple.getBlocked() != null) { for (LeftTuple leftTuple = rightTuple.getBlocked(); leftTuple != null; ) { LeftTuple temp = leftTuple.getBlockedNext(); leftTuple.clearBlocker(); if (leftTuple.getStagedType() == LeftTuple.UPDATE) { // ignore, as it will get processed via left iteration. Children cannot be processed // twice leftTuple = temp; continue; } constraints.updateFromTuple(contextEntry, wm, leftTuple); if (useComparisonIndex) { rootBlocker = rtm.getFirst(leftTuple, null, it); } // we know that older tuples have been checked so continue next for (RightTuple newBlocker = rootBlocker; newBlocker != null; newBlocker = (RightTuple) it.next(newBlocker)) { if (constraints.isAllowedCachedLeft(contextEntry, newBlocker.getFactHandle())) { leftTuple.setBlocker(newBlocker); newBlocker.addBlocked(leftTuple); break; } } if (leftTuple.getBlocker() == null) { // was previous blocked and not in memory, so add ltm.add(leftTuple); trgLeftTuples.addInsert( sink.createLeftTuple(leftTuple, sink, rightTuple.getPropagationContext(), true)); } leftTuple = temp; } } rightTuple.nullBlocked(); rightTuple.clearStaged(); rightTuple = next; } constraints.resetTuple(contextEntry); }
public static void dpUpdatesExistentialReorderRightMemory( BetaMemory bm, BetaNode betaNode, RightTupleSets srcRightTuples) { RightTupleMemory rtm = bm.getRightTupleMemory(); boolean resumeFromCurrent = !(betaNode.isIndexedUnificationJoin() || rtm.getIndexType().isComparison()); // remove all the staged rightTuples from the memory before to readd them all // this is to avoid split bucket when an updated rightTuple hasn't been moved yet // and so it is the first entry in the wrong bucket for (RightTuple rightTuple = srcRightTuples.getUpdateFirst(); rightTuple != null; ) { RightTuple next = rightTuple.getStagedNext(); if (rightTuple.getMemory() != null) { rightTuple.setTempRightTupleMemory(rightTuple.getMemory()); if (resumeFromCurrent) { if (rightTuple.getBlocked() != null) { // look for a non-staged right tuple first forward ... RightTuple tempRightTuple = (RightTuple) rightTuple.getNext(); while (tempRightTuple != null && tempRightTuple.getStagedType() != LeftTuple.NONE) { // next cannot be an updated or deleted rightTuple tempRightTuple = (RightTuple) tempRightTuple.getNext(); } // ... and if cannot find one try backward if (tempRightTuple == null) { tempRightTuple = (RightTuple) rightTuple.getPrevious(); while (tempRightTuple != null && tempRightTuple.getStagedType() != LeftTuple.NONE) { // next cannot be an updated or deleted rightTuple tempRightTuple = (RightTuple) tempRightTuple.getPrevious(); } } rightTuple.setTempNextRightTuple(tempRightTuple); } } rightTuple.setTempBlocked(rightTuple.getBlocked()); rightTuple.nullBlocked(); rtm.remove(rightTuple); } rightTuple = next; } for (RightTuple rightTuple = srcRightTuples.getUpdateFirst(); rightTuple != null; ) { RightTuple next = rightTuple.getStagedNext(); if (rightTuple.getTempRightTupleMemory() != null) { rtm.add(rightTuple); if (resumeFromCurrent) { RightTuple tempRightTuple = rightTuple.getTempNextRightTuple(); if (rightTuple.getBlocked() != null && tempRightTuple == null && rightTuple.getMemory() == rightTuple.getTempRightTupleMemory()) { // the next RightTuple was null, but current RightTuple was added back into the same // bucket, so reset as root blocker to re-match can be attempted rightTuple.setTempNextRightTuple(rightTuple); } } for (LeftTuple childLeftTuple = rightTuple.getFirstChild(); childLeftTuple != null; ) { LeftTuple childNext = childLeftTuple.getRightParentNext(); childLeftTuple.reAddLeft(); childLeftTuple = childNext; } } rightTuple = next; } }