*/
package org.opendaylight.yangtools.yang.data.impl.schema.tree;
+import com.google.common.base.Optional;
+import com.google.common.base.Preconditions;
+import com.google.common.collect.Iterables;
+import java.util.Collection;
import java.util.Map.Entry;
-
-import javax.annotation.concurrent.GuardedBy;
-
+import java.util.concurrent.atomic.AtomicIntegerFieldUpdater;
import org.opendaylight.yangtools.yang.data.api.YangInstanceIdentifier;
import org.opendaylight.yangtools.yang.data.api.YangInstanceIdentifier.PathArgument;
import org.opendaylight.yangtools.yang.data.api.schema.NormalizedNode;
-import org.opendaylight.yangtools.yang.data.api.schema.NormalizedNodeContainer;
+import org.opendaylight.yangtools.yang.data.api.schema.NormalizedNodes;
import org.opendaylight.yangtools.yang.data.api.schema.tree.DataTreeModification;
-import org.opendaylight.yangtools.yang.data.api.schema.tree.ModificationType;
+import org.opendaylight.yangtools.yang.data.api.schema.tree.DataTreeModificationCursor;
+import org.opendaylight.yangtools.yang.data.api.schema.tree.StoreTreeNodes;
import org.opendaylight.yangtools.yang.data.api.schema.tree.spi.TreeNode;
import org.opendaylight.yangtools.yang.data.api.schema.tree.spi.Version;
-import org.opendaylight.yangtools.yang.data.impl.schema.NormalizedNodeUtils;
import org.slf4j.Logger;
import org.slf4j.LoggerFactory;
-import com.google.common.base.Optional;
-import com.google.common.base.Preconditions;
-
final class InMemoryDataTreeModification implements DataTreeModification {
+ private static final AtomicIntegerFieldUpdater<InMemoryDataTreeModification> UPDATER =
+ AtomicIntegerFieldUpdater.newUpdater(InMemoryDataTreeModification.class, "sealed");
private static final Logger LOG = LoggerFactory.getLogger(InMemoryDataTreeModification.class);
+
private final RootModificationApplyOperation strategyTree;
private final InMemoryDataTreeSnapshot snapshot;
private final ModifiedNode rootNode;
private final Version version;
- @GuardedBy("this")
- private boolean sealed = false;
+ private volatile int sealed = 0;
InMemoryDataTreeModification(final InMemoryDataTreeSnapshot snapshot, final RootModificationApplyOperation resolver) {
this.snapshot = Preconditions.checkNotNull(snapshot);
this.strategyTree = Preconditions.checkNotNull(resolver).snapshot();
- this.rootNode = ModifiedNode.createUnmodified(snapshot.getRootNode(), false);
+ this.rootNode = ModifiedNode.createUnmodified(snapshot.getRootNode(), strategyTree.getChildPolicy());
+
/*
* We could allocate version beforehand, since Version contract
- * states two allocated version must be allways different.
- *
+ * states two allocated version must be always different.
+ *
* Preallocating version simplifies scenarios such as
* chaining of modifications, since version for particular
* node in modification and in data tree (if successfully
- * commited) will be same and will not change.
- *
+ * committed) will be same and will not change.
*/
this.version = snapshot.getRootNode().getSubtreeVersion().next();
}
}
@Override
- public synchronized void write(final YangInstanceIdentifier path, final NormalizedNode<?, ?> value) {
+ public void write(final YangInstanceIdentifier path, final NormalizedNode<?, ?> data) {
checkSealed();
- resolveModificationFor(path).write(value);
+
+ resolveModificationFor(path).write(data);
}
@Override
- public synchronized void merge(final YangInstanceIdentifier path, final NormalizedNode<?, ?> data) {
+ public void merge(final YangInstanceIdentifier path, final NormalizedNode<?, ?> data) {
checkSealed();
- mergeImpl(resolveModificationFor(path),data);
- }
-
- private void mergeImpl(final OperationWithModification op,final NormalizedNode<?,?> data) {
- if(data instanceof NormalizedNodeContainer<?,?,?>) {
- @SuppressWarnings({ "rawtypes", "unchecked" })
- NormalizedNodeContainer<?,?,NormalizedNode<PathArgument, ?>> dataContainer = (NormalizedNodeContainer) data;
- for(NormalizedNode<PathArgument, ?> child : dataContainer.getValue()) {
- PathArgument childId = child.getIdentifier();
- mergeImpl(op.forChild(childId), child);
- }
- }
- op.merge(data);
+ resolveModificationFor(path).merge(data);
}
@Override
- public synchronized void delete(final YangInstanceIdentifier path) {
+ public void delete(final YangInstanceIdentifier path) {
checkSealed();
+
resolveModificationFor(path).delete();
}
@Override
- public synchronized Optional<NormalizedNode<?, ?>> readNode(final YangInstanceIdentifier path) {
+ public Optional<NormalizedNode<?, ?>> readNode(final YangInstanceIdentifier path) {
/*
* Walk the tree from the top, looking for the first node between root and
* the requested path which has been modified. If no such node exists,
* we use the node itself.
*/
- final Entry<YangInstanceIdentifier, ModifiedNode> entry = TreeNodeUtils.findClosestsOrFirstMatch(rootNode, path, ModifiedNode.IS_TERMINAL_PREDICATE);
+ final Entry<YangInstanceIdentifier, ModifiedNode> entry = StoreTreeNodes.findClosestsOrFirstMatch(rootNode, path, ModifiedNode.IS_TERMINAL_PREDICATE);
final YangInstanceIdentifier key = entry.getKey();
final ModifiedNode mod = entry.getValue();
final Optional<TreeNode> result = resolveSnapshot(key, mod);
if (result.isPresent()) {
NormalizedNode<?, ?> data = result.get().getData();
- return NormalizedNodeUtils.findNode(key, data, path);
+ return NormalizedNodes.findNode(key, data, path);
} else {
return Optional.absent();
}
}
- private Optional<TreeNode> resolveSnapshot(final YangInstanceIdentifier path,
- final ModifiedNode modification) {
- final Optional<Optional<TreeNode>> potentialSnapshot = modification.getSnapshotCache();
- if(potentialSnapshot.isPresent()) {
- return potentialSnapshot.get();
+ private Optional<TreeNode> resolveSnapshot(final YangInstanceIdentifier path, final ModifiedNode modification) {
+ final Optional<TreeNode> potentialSnapshot = modification.getSnapshot();
+ if (potentialSnapshot != null) {
+ return potentialSnapshot;
}
try {
return resolveModificationStrategy(path).apply(modification, modification.getOriginal(),
version);
} catch (Exception e) {
- LOG.error("Could not create snapshot for {}:{}", path,modification,e);
+ LOG.error("Could not create snapshot for {}:{}", path, modification, e);
throw e;
}
}
- private ModificationApplyOperation resolveModificationStrategy(final YangInstanceIdentifier path) {
- LOG.trace("Resolving modification apply strategy for {}", path);
- if(rootNode.getType() == ModificationType.UNMODIFIED) {
+ private void upgradeIfPossible() {
+ if (rootNode.getOperation() == LogicalOperation.NONE) {
strategyTree.upgradeIfPossible();
}
+ }
- return TreeNodeUtils.<ModificationApplyOperation>findNodeChecked(strategyTree, path);
+ private ModificationApplyOperation resolveModificationStrategy(final YangInstanceIdentifier path) {
+ LOG.trace("Resolving modification apply strategy for {}", path);
+
+ upgradeIfPossible();
+ return StoreTreeNodes.<ModificationApplyOperation>findNodeChecked(strategyTree, path);
}
private OperationWithModification resolveModificationFor(final YangInstanceIdentifier path) {
+ upgradeIfPossible();
+
+ /*
+ * Walk the strategy and modification trees in-sync, creating modification nodes as needed.
+ *
+ * If the user has provided wrong input, we may end up with a bunch of TOUCH nodes present
+ * ending with an empty one, as we will throw the exception below. This fact could end up
+ * being a problem, as we'd have bunch of phantom operations.
+ *
+ * That is fine, as we will prune any empty TOUCH nodes in the last phase of the ready
+ * process.
+ */
+ ModificationApplyOperation operation = strategyTree;
ModifiedNode modification = rootNode;
- // We ensure strategy is present.
- ModificationApplyOperation operation = resolveModificationStrategy(path);
- boolean isOrdered = true;
- if (operation instanceof SchemaAwareApplyOperation) {
- isOrdered = ((SchemaAwareApplyOperation) operation).isOrdered();
- }
+ int i = 1;
for (PathArgument pathArg : path.getPathArguments()) {
- modification = modification.modifyChild(pathArg, isOrdered);
+ Optional<ModificationApplyOperation> potential = operation.getChild(pathArg);
+ if (!potential.isPresent()) {
+ throw new IllegalArgumentException(String.format("Child %s is not present in schema tree.",
+ Iterables.toString(Iterables.limit(path.getPathArguments(), i))));
+ }
+ operation = potential.get();
+ ++i;
+
+ modification = modification.modifyChild(pathArg, operation.getChildPolicy());
}
- return OperationWithModification.from(operation, modification);
- }
- @Override
- public synchronized void ready() {
- Preconditions.checkState(!sealed, "Attempted to seal an already-sealed Data Tree.");
- sealed = true;
- rootNode.seal();
+ return OperationWithModification.from(operation, modification);
}
- @GuardedBy("this")
private void checkSealed() {
- Preconditions.checkState(!sealed, "Data Tree is sealed. No further modifications allowed.");
+ Preconditions.checkState(sealed == 0, "Data Tree is sealed. No further modifications allowed.");
}
@Override
}
@Override
- public synchronized DataTreeModification newModification() {
- Preconditions.checkState(sealed, "Attempted to chain on an unsealed modification");
+ public DataTreeModification newModification() {
+ Preconditions.checkState(sealed == 1, "Attempted to chain on an unsealed modification");
- if(rootNode.getType() == ModificationType.UNMODIFIED) {
+ if (rootNode.getOperation() == LogicalOperation.NONE) {
+ // Simple fast case: just use the underlying modification
return snapshot.newModification();
}
/*
- * We will use preallocated version, this means returned snapshot will
- * have same version each time this method is called.
+ * We will use preallocated version, this means returned snapshot will
+ * have same version each time this method is called.
*/
TreeNode originalSnapshotRoot = snapshot.getRootNode();
Optional<TreeNode> tempRoot = strategyTree.apply(rootNode, Optional.of(originalSnapshotRoot), version);
Version getVersion() {
return version;
}
+
+ private static void applyChildren(final DataTreeModificationCursor cursor, final ModifiedNode node) {
+ final Collection<ModifiedNode> children = node.getChildren();
+ if (!children.isEmpty()) {
+ cursor.enter(node.getIdentifier());
+ for (ModifiedNode child : children) {
+ applyNode(cursor, child);
+ }
+ cursor.exit();
+ }
+ }
+
+ private static void applyNode(final DataTreeModificationCursor cursor, final ModifiedNode node) {
+ switch (node.getOperation()) {
+ case NONE:
+ break;
+ case DELETE:
+ cursor.delete(node.getIdentifier());
+ break;
+ case MERGE:
+ cursor.merge(node.getIdentifier(), node.getWrittenValue());
+ applyChildren(cursor, node);
+ break;
+ case TOUCH:
+ // TODO: we could improve efficiency of cursor use if we could understand
+ // nested TOUCH operations. One way of achieving that would be a proxy
+ // cursor, which would keep track of consecutive enter and exit calls
+ // and coalesce them.
+ applyChildren(cursor, node);
+ break;
+ case WRITE:
+ cursor.write(node.getIdentifier(), node.getWrittenValue());
+ applyChildren(cursor, node);
+ break;
+ default:
+ throw new IllegalArgumentException("Unhandled node operation " + node.getOperation());
+ }
+ }
+
+ @Override
+ public void applyToCursor(final DataTreeModificationCursor cursor) {
+ for (ModifiedNode child : rootNode.getChildren()) {
+ applyNode(cursor, child);
+ }
+ }
+
+ @Override
+ public void ready() {
+ final boolean wasRunning = UPDATER.compareAndSet(this, 0, 1);
+ Preconditions.checkState(wasRunning, "Attempted to seal an already-sealed Data Tree.");
+
+ AbstractReadyIterator current = AbstractReadyIterator.create(rootNode);
+ do {
+ current = current.process();
+ } while (current != null);
+ }
+
}