import static java.util.Objects.requireNonNull;
import com.google.common.annotations.Beta;
+import com.google.common.annotations.VisibleForTesting;
import com.google.common.base.MoreObjects;
import com.google.common.base.VerifyException;
+import com.google.common.collect.Collections2;
import com.google.common.collect.ImmutableList;
+import com.google.common.collect.Iterables;
import com.google.common.collect.Iterators;
import java.util.ArrayDeque;
-import java.util.Deque;
+import java.util.Collection;
import java.util.Iterator;
import java.util.List;
import java.util.NoSuchElementException;
import org.opendaylight.yangtools.yang.xpath.api.YangLocationPath.QNameStep;
import org.opendaylight.yangtools.yang.xpath.api.YangLocationPath.Step;
import org.opendaylight.yangtools.yang.xpath.api.YangXPathAxis;
+import org.slf4j.LoggerFactory;
/**
* A state tracking utility for walking {@link EffectiveModelContext}'s contents along schema/grouping namespaces. This
@Override
public List<EffectiveStatement<?, ?>> statementPath() {
- return ImmutableList.copyOf(deque.descendingIterator());
+ return ImmutableList.copyOf(deque);
}
/**
}
}
+ private static final String VERIFY_DEFAULT_SCHEMA_TREE_INFERENCE_PROP =
+ "org.opendaylight.yangtools.yang.model.util.SchemaInferenceStack.verifyDefaultSchemaTreeInference";
+ private static final boolean VERIFY_DEFAULT_SCHEMA_TREE_INFERENCE =
+ Boolean.getBoolean(VERIFY_DEFAULT_SCHEMA_TREE_INFERENCE_PROP);
+
+ static {
+ if (VERIFY_DEFAULT_SCHEMA_TREE_INFERENCE) {
+ LoggerFactory.getLogger(SchemaInferenceStack.class)
+ .info("SchemaTreeStack.ofInference(DefaultSchemaTreeInference) argument is being verified");
+ }
+ }
+
private final @NonNull EffectiveModelContext effectiveModel;
private final ArrayDeque<EffectiveStatement<?, ?>> deque;
* @throws IllegalArgumentException if {@code inference} cannot be resolved to a valid stack
*/
public static @NonNull SchemaInferenceStack ofInference(final SchemaTreeInference inference) {
- return of(inference.getEffectiveModelContext(), inference.toSchemaNodeIdentifier());
+ return inference instanceof DefaultSchemaTreeInference ? ofInference((DefaultSchemaTreeInference) inference)
+ : of(inference.getEffectiveModelContext(), inference.toSchemaNodeIdentifier());
+ }
+
+ /**
+ * Create a new stack from an {@link DefaultSchemaTreeInference}. The argument is nominally trusted to be an
+ * accurate representation of the schema tree.
+ *
+ * <p>
+ * Run-time verification of {@code inference} can be enabled by setting the
+ * {@value #VERIFY_DEFAULT_SCHEMA_TREE_INFERENCE_PROP} system property to {@code true}.
+ *
+ * @param inference DefaultSchemaTreeInference to use for initialization
+ * @return A new stack
+ * @throws NullPointerException if {@code inference} is null
+ * @throws IllegalArgumentException if {@code inference} refers to a missing module or when verification is enabled
+ * and it does not match its context's scheam tree
+ */
+ public static @NonNull SchemaInferenceStack ofInference(final DefaultSchemaTreeInference inference) {
+ return VERIFY_DEFAULT_SCHEMA_TREE_INFERENCE ? ofUntrusted(inference) : ofTrusted(inference);
+ }
+
+ private static @NonNull SchemaInferenceStack ofTrusted(final DefaultSchemaTreeInference inference) {
+ final var path = inference.statementPath();
+ final var ret = new SchemaInferenceStack(inference.getEffectiveModelContext(), path.size());
+ ret.currentModule = ret.getModule(path.get(0).argument());
+ ret.deque.addAll(path);
+ return ret;
+ }
+
+ @VisibleForTesting
+ static @NonNull SchemaInferenceStack ofUntrusted(final DefaultSchemaTreeInference inference) {
+ final var ret = of(inference.getEffectiveModelContext(), inference.toSchemaNodeIdentifier());
+ if (!Iterables.elementsEqual(ret.deque, inference.statementPath())) {
+ throw new IllegalArgumentException("Provided " + inference + " is not consistent with resolved path "
+ + ret.toSchemaTreeInference());
+ }
+ return ret;
}
/**
* @throws IllegalStateException if the stack is empty
*/
public @NonNull EffectiveStatement<?, ?> currentStatement() {
- return checkNonNullState(deque.peekFirst());
+ return checkNonNullState(deque.peekLast());
}
/**
*/
public @NonNull ChoiceEffectiveStatement enterChoice(final QName nodeIdentifier) {
final QName nodeId = requireNonNull(nodeIdentifier);
- final EffectiveStatement<?, ?> parent = deque.peek();
+ final EffectiveStatement<?, ?> parent = deque.peekLast();
if (parent instanceof ChoiceEffectiveStatement) {
return enterChoice((ChoiceEffectiveStatement) parent, nodeId);
}
.map(ChoiceEffectiveStatement.class::cast);
if (optMatch.isPresent()) {
final SchemaTreeEffectiveStatement<?> match = optMatch.orElseThrow();
- deque.push(match);
+ deque.addLast(match);
clean = false;
return (ChoiceEffectiveStatement) match;
}
* @throws IllegalStateException if this stack is not empty
*/
public @NonNull YangDataEffectiveStatement enterYangData(final QNameModule namespace, final String name) {
- final EffectiveStatement<?, ?> parent = deque.peekFirst();
+ final EffectiveStatement<?, ?> parent = deque.peekLast();
checkState(parent == null, "Cannot lookup yang-data in a non-empty stack");
final String templateName = requireNonNull(name);
.findFirst()
.orElseThrow(
() -> new IllegalArgumentException("yang-data " + templateName + " not present in " + namespace));
- deque.push(ret);
+ deque.addLast(ret);
currentModule = module;
return ret;
}
* @throws NoSuchElementException if this stack is empty
*/
public @NonNull EffectiveStatement<?, ?> exit() {
- final EffectiveStatement<?, ?> prev = deque.pop();
+ final EffectiveStatement<?, ?> prev = deque.removeLast();
if (prev instanceof GroupingEffectiveStatement) {
--groupingDepth;
}
public @NonNull DataTreeEffectiveStatement<?> exitToDataTree() {
final EffectiveStatement<?, ?> child = exit();
checkState(child instanceof DataTreeEffectiveStatement, "Unexpected current %s", child);
- EffectiveStatement<?, ?> parent = deque.peekFirst();
+ EffectiveStatement<?, ?> parent = deque.peekLast();
while (parent instanceof ChoiceEffectiveStatement || parent instanceof CaseEffectiveStatement) {
- deque.pollFirst();
- parent = deque.peekFirst();
+ deque.pollLast();
+ parent = deque.peekLast();
}
checkState(parent == null || parent instanceof DataTreeAwareEffectiveStatement, "Unexpected parent %s", parent);
return (DataTreeEffectiveStatement<?>) child;
}
-
@Override
public TypeDefinition<?> resolveLeafref(final LeafrefTypeDefinition type) {
final SchemaInferenceStack tmp = copy();
private @NonNull EffectiveStatement<?, ?> resolveLocationPath(final YangLocationPath path) {
// get the default namespace before we clear and loose our deque
- final QNameModule defaultNamespace = deque.isEmpty() ? null : ((QName) deque.peek().argument()).getModule();
+ final QNameModule defaultNamespace = deque.isEmpty() ? null : ((QName) deque.peekLast().argument()).getModule();
if (path.isAbsolute()) {
clear();
}
* @throws IllegalStateException if current state cannot be converted to a {@link SchemaTreeInference}
*/
public @NonNull SchemaTreeInference toSchemaTreeInference() {
- return DefaultSchemaTreeInference.of(getEffectiveModelContext(), toSchemaNodeIdentifier());
+ checkState(inInstantiatedContext(), "Cannot convert uninstantiated context %s", this);
+ final var cleanDeque = clean ? deque : reconstructSchemaInferenceStack().deque;
+ return DefaultSchemaTreeInference.unsafeOf(getEffectiveModelContext(), cleanDeque.stream()
+ .map(stmt -> (SchemaTreeEffectiveStatement<?>) stmt)
+ .collect(ImmutableList.toImmutableList()));
}
/**
*/
public @NonNull Absolute toSchemaNodeIdentifier() {
checkState(inInstantiatedContext(), "Cannot convert uninstantiated context %s", this);
- return Absolute.of(ImmutableList.<QName>builderWithExpectedSize(deque.size())
- .addAll(simplePathFromRoot())
- .build());
+ return Absolute.of(simplePathFromRoot());
}
/**
*/
@Deprecated
public @NonNull SchemaPath toSchemaPath() {
- SchemaPath ret = SchemaPath.ROOT;
- final Iterator<QName> it = simplePathFromRoot();
- while (it.hasNext()) {
- ret = ret.createChild(it.next());
- }
- return ret;
+ return SchemaPath.create(simplePathFromRoot(), true);
}
/**
*/
@Deprecated
public @NonNull Iterator<QName> schemaPathIterator() {
- return Iterators.unmodifiableIterator(simplePathFromRoot());
+ return Iterators.unmodifiableIterator(simplePathFromRoot().iterator());
}
@Override
public String toString() {
- return MoreObjects.toStringHelper(this).add("stack", deque).toString();
+ return MoreObjects.toStringHelper(this).add("path", deque).toString();
}
private @NonNull GroupingEffectiveStatement pushGrouping(final @NonNull QName nodeIdentifier) {
- final EffectiveStatement<?, ?> parent = deque.peekFirst();
+ final EffectiveStatement<?, ?> parent = deque.peekLast();
return parent != null ? pushGrouping(parent, nodeIdentifier) : pushFirstGrouping(nodeIdentifier);
}
.filter(stmt -> nodeIdentifier.equals(stmt.argument()))
.findFirst()
.orElseThrow(() -> notPresent(parent, "Grouping", nodeIdentifier));
- deque.push(ret);
+ deque.addLast(ret);
++groupingDepth;
return ret;
}
}
private @NonNull SchemaTreeEffectiveStatement<?> pushSchema(final @NonNull QName nodeIdentifier) {
- final EffectiveStatement<?, ?> parent = deque.peekFirst();
+ final EffectiveStatement<?, ?> parent = deque.peekLast();
return parent != null ? pushSchema(parent, nodeIdentifier) : pushFirstSchema(nodeIdentifier);
}
final @NonNull SchemaTreeAwareEffectiveStatement<?, ?> parent, final @NonNull QName nodeIdentifier) {
final SchemaTreeEffectiveStatement<?> ret = parent.findSchemaTreeNode(nodeIdentifier)
.orElseThrow(() -> notPresent(parent, "Schema tree child ", nodeIdentifier));
- deque.push(ret);
+ deque.addLast(ret);
return ret;
}
}
private @NonNull DataTreeEffectiveStatement<?> pushData(final @NonNull QName nodeIdentifier) {
- final EffectiveStatement<?, ?> parent = deque.peekFirst();
+ final EffectiveStatement<?, ?> parent = deque.peekLast();
return parent != null ? pushData(parent, nodeIdentifier) : pushFirstData(nodeIdentifier);
}
final @NonNull QName nodeIdentifier) {
final DataTreeEffectiveStatement<?> ret = parent.findDataTreeNode(nodeIdentifier)
.orElseThrow(() -> notPresent(parent, "Data tree child", nodeIdentifier));
- deque.push(ret);
+ deque.addLast(ret);
clean = false;
return ret;
}
}
private @NonNull TypedefEffectiveStatement pushTypedef(final @NonNull QName nodeIdentifier) {
- final EffectiveStatement<?, ?> parent = deque.peekFirst();
+ final EffectiveStatement<?, ?> parent = deque.peekLast();
return parent != null ? pushTypedef(parent, nodeIdentifier) : pushFirstTypedef(nodeIdentifier);
}
final @NonNull QName nodeIdentifier) {
final TypedefEffectiveStatement ret = parent.get(TypedefNamespace.class, nodeIdentifier)
.orElseThrow(() -> notPresent(parent, "Typedef", nodeIdentifier));
- deque.push(ret);
+ deque.addLast(ret);
return ret;
}
// Unified access to queue iteration for addressing purposes. Since we keep 'logical' steps as executed by user
// at this point, conversion to SchemaNodeIdentifier may be needed. We dispatch based on 'clean'.
- private Iterator<QName> simplePathFromRoot() {
- return clean ? iterateQNames() : reconstructQNames();
+ private Collection<QName> simplePathFromRoot() {
+ return clean ? qnames() : reconstructQNames();
}
- private Iterator<QName> iterateQNames() {
- return Iterators.transform(deque.descendingIterator(), stmt -> {
+ private Collection<QName> qnames() {
+ return Collections2.transform(deque, stmt -> {
final Object argument = stmt.argument();
verify(argument instanceof QName, "Unexpected statement %s", stmt);
return (QName) argument;
// So there are some data tree steps in the stack... we essentially need to convert a data tree item into a series
// of schema tree items. This means at least N searches, but after they are done, we get an opportunity to set the
// clean flag.
- private Iterator<QName> reconstructQNames() {
+ private Collection<QName> reconstructQNames() {
+ return reconstructSchemaInferenceStack().qnames();
+ }
+
+ private SchemaInferenceStack reconstructSchemaInferenceStack() {
// Let's walk all statements and decipher them into a temporary stack
final SchemaInferenceStack tmp = new SchemaInferenceStack(effectiveModel, deque.size());
- final Iterator<EffectiveStatement<?, ?>> it = deque.descendingIterator();
+ final Iterator<EffectiveStatement<?, ?>> it = deque.iterator();
while (it.hasNext()) {
final EffectiveStatement<?, ?> stmt = it.next();
// Order of checks is significant
}
// if the sizes match, we did not jump through hoops. let's remember that for future.
- clean = deque.size() == tmp.deque.size();
- return tmp.iterateQNames();
+ if (deque.size() == tmp.deque.size()) {
+ clean = true;
+ return this;
+ }
+ return tmp;
}
private void resolveChoiceSteps(final @NonNull QName nodeIdentifier) {
- final EffectiveStatement<?, ?> parent = deque.peekFirst();
+ final EffectiveStatement<?, ?> parent = deque.peekLast();
if (parent instanceof ChoiceEffectiveStatement) {
resolveChoiceSteps((ChoiceEffectiveStatement) parent, nodeIdentifier);
} else {
final CaseEffectiveStatement caze = (CaseEffectiveStatement) stmt;
final SchemaTreeEffectiveStatement<?> found = caze.findSchemaTreeNode(nodeIdentifier).orElse(null);
if (found instanceof ChoiceEffectiveStatement) {
- deque.push(caze);
- deque.push(found);
+ deque.addLast(caze);
+ deque.addLast(found);
return;
}
}
}
private void resolveDataTreeSteps(final @NonNull QName nodeIdentifier) {
- final EffectiveStatement<?, ?> parent = deque.peekFirst();
+ final EffectiveStatement<?, ?> parent = deque.peekLast();
if (parent != null) {
verify(parent instanceof SchemaTreeAwareEffectiveStatement, "Unexpected parent %s", parent);
resolveDataTreeSteps((SchemaTreeAwareEffectiveStatement<?, ?>) parent, nodeIdentifier);
final SchemaTreeEffectiveStatement<?> found = parent.findSchemaTreeNode(nodeIdentifier).orElse(null);
if (found instanceof DataTreeEffectiveStatement) {
// ... and it did, we are done
- deque.push(found);
+ deque.addLast(found);
return;
}
// Alright, so now it's down to filtering choice/case statements. For that we keep some globally-reused state
// and employ a recursive match.
- final Deque<EffectiveStatement<QName, ?>> match = new ArrayDeque<>();
+ final var match = new ArrayDeque<EffectiveStatement<QName, ?>>();
for (EffectiveStatement<?, ?> stmt : parent.effectiveSubstatements()) {
if (stmt instanceof ChoiceEffectiveStatement
&& searchChoice(match, (ChoiceEffectiveStatement) stmt, nodeIdentifier)) {
- match.descendingIterator().forEachRemaining(deque::push);
+ deque.addAll(match);
return;
}
}
throw new VerifyException("Failed to resolve " + nodeIdentifier + " in " + parent);
}
- private static boolean searchCase(final @NonNull Deque<EffectiveStatement<QName, ?>> result,
+ private static boolean searchCase(final @NonNull ArrayDeque<EffectiveStatement<QName, ?>> result,
final @NonNull CaseEffectiveStatement parent, final @NonNull QName nodeIdentifier) {
- result.push(parent);
+ result.addLast(parent);
for (EffectiveStatement<?, ?> stmt : parent.effectiveSubstatements()) {
if (stmt instanceof DataTreeEffectiveStatement && nodeIdentifier.equals(stmt.argument())) {
- result.push((DataTreeEffectiveStatement<?>) stmt);
+ result.addLast((DataTreeEffectiveStatement<?>) stmt);
return true;
}
if (stmt instanceof ChoiceEffectiveStatement
return true;
}
}
- result.pop();
+ result.removeLast();
return false;
}
- private static boolean searchChoice(final @NonNull Deque<EffectiveStatement<QName, ?>> result,
+ private static boolean searchChoice(final @NonNull ArrayDeque<EffectiveStatement<QName, ?>> result,
final @NonNull ChoiceEffectiveStatement parent, final @NonNull QName nodeIdentifier) {
- result.push(parent);
+ result.addLast(parent);
for (EffectiveStatement<?, ?> stmt : parent.effectiveSubstatements()) {
if (stmt instanceof CaseEffectiveStatement
&& searchCase(result, (CaseEffectiveStatement) stmt, nodeIdentifier)) {
return true;
}
}
- result.pop();
+ result.removeLast();
return false;
}