@NonNull
public IAndroidTarget[] getMissingTargets() {
synchronized (mLocalPackages) {
if (mCachedMissingTargets == null) {
Map<MissingTarget, MissingTarget> result = Maps.newHashMap();
Set<ISystemImage> seen = Sets.newHashSet();
for (IAndroidTarget target : getTargets()) {
Collections.addAll(seen, target.getSystemImages());
}
for (LocalPkgInfo local : getPkgsInfos(PkgType.PKG_ADDON_SYS_IMAGE)) {
LocalAddonSysImgPkgInfo info = (LocalAddonSysImgPkgInfo) local;
ISystemImage image = info.getSystemImage();
if (!seen.contains(image)) {
addOrphanedSystemImage(image, info.getDesc(), result);
}
}
for (LocalPkgInfo local : getPkgsInfos(PkgType.PKG_SYS_IMAGE)) {
LocalSysImgPkgInfo info = (LocalSysImgPkgInfo) local;
ISystemImage image = info.getSystemImage();
if (!seen.contains(image)) {
addOrphanedSystemImage(image, info.getDesc(), result);
}
}
mCachedMissingTargets = result.keySet();
}
return mCachedMissingTargets.toArray(new IAndroidTarget[mCachedMissingTargets.size()]);
}
}
public NBTStorage(final File file, final String name) {
this.root = (Map<String, Tag>) Maps.newHashMap();
this.file = file;
if (!this.file.exists()) {
this.create();
}
this.name = name;
}
private void writeDelegateMethods(
final ClassVisitor visitor,
final Type generatedType,
StructSchema<?> delegateSchema,
Set<Class<?>> typesToDelegate) {
Class<?> delegateClass = delegateSchema.getType().getConcreteClass();
Type delegateType = Type.getType(delegateClass);
Map<Equivalence.Wrapper<Method>, Map<Class<?>, Method>> methodsToDelegate = Maps.newHashMap();
for (Class<?> typeToDelegate : typesToDelegate) {
for (Method methodToDelegate : typeToDelegate.getMethods()) {
if (ModelSchemaUtils.isIgnoredMethod(methodToDelegate)) {
continue;
}
Equivalence.Wrapper<Method> methodKey = METHOD_EQUIVALENCE.wrap(methodToDelegate);
Map<Class<?>, Method> methodsByReturnType = methodsToDelegate.get(methodKey);
if (methodsByReturnType == null) {
methodsByReturnType = Maps.newHashMap();
methodsToDelegate.put(methodKey, methodsByReturnType);
}
methodsByReturnType.put(methodToDelegate.getReturnType(), methodToDelegate);
}
}
Set<Equivalence.Wrapper<Method>> delegateMethodKeys =
ImmutableSet.copyOf(
Iterables.transform(
Arrays.asList(delegateClass.getMethods()),
new Function<Method, Equivalence.Wrapper<Method>>() {
@Override
public Equivalence.Wrapper<Method> apply(Method method) {
return METHOD_EQUIVALENCE.wrap(method);
}
}));
for (Map.Entry<Equivalence.Wrapper<Method>, Map<Class<?>, Method>> entry :
methodsToDelegate.entrySet()) {
Equivalence.Wrapper<Method> methodKey = entry.getKey();
if (!delegateMethodKeys.contains(methodKey)) {
continue;
}
Map<Class<?>, Method> methodsByReturnType = entry.getValue();
for (Method methodToDelegate : methodsByReturnType.values()) {
writeDelegatedMethod(visitor, generatedType, delegateType, methodToDelegate);
}
}
}
private static Map<ClassDescriptor, JetType> getSuperclassToSupertypeMap(
ClassDescriptor containingClass) {
Map<ClassDescriptor, JetType> superclassToSupertype = Maps.newHashMap();
for (JetType supertype : TypeUtils.getAllSupertypes(containingClass.getDefaultType())) {
ClassifierDescriptor superclass = supertype.getConstructor().getDeclarationDescriptor();
assert superclass instanceof ClassDescriptor;
superclassToSupertype.put((ClassDescriptor) superclass, supertype);
}
return superclassToSupertype;
}
public List<Vertex> getProductAssociations(Vertex v) {
Map<Vertex, Edge> adjacent = Maps.newHashMap(graph.row(v));
adjacent.putAll(graph.column(v));
return adjacent
.entrySet()
.stream()
.sorted((e1, e2) -> e2.getValue().weight - e1.getValue().weight)
.map(Map.Entry::getKey)
.collect(Collectors.toList());
}
/**
* Rest配置中心
*
* @author Peter Zhang
*/
public class RestConfigurations {
private static Map<String, RestServiceConfiguration> CONFIG_FOR_NAME = Maps.newHashMap();
private static Map<String, RestServiceConfiguration> CONFIG_FOR_SERVICE_NAME = Maps.newHashMap();
private static Map<String, RestServiceConfiguration> CONFIG_FOR_ENV = Maps.newHashMap();
private static RestServiceConfiguration DEFAULT_CONFIG;
/**
* 注册配置
*
* @param configuration Rest服务基础配置
*/
public static void register(RestServiceConfiguration configuration) {
CONFIG_FOR_NAME.put(configuration.getConfigurationName(), configuration);
CONFIG_FOR_SERVICE_NAME.put(configuration.getCgiServiceName(), configuration);
CONFIG_FOR_ENV.put(configuration.getEnvironment(), configuration);
DEFAULT_CONFIG = configuration;
}
/** 获取默认配置对象 */
public static RestServiceConfiguration getDefaultConfiguration() {
return DEFAULT_CONFIG;
}
/**
* 根据环境获取配置
*
* @param environment 环境
*/
public static RestServiceConfiguration getConfigByEnvironment(String environment) {
return CONFIG_FOR_ENV.get(environment);
}
}
/**
* 按照对应关系对 aitID:threadInfo-> 1:n 对N从大到小排序 处理MulitMap中的数据,key:value->1:n 取出<key, n>
* 对n降序排序后,取得序列后的List<Map.Entry<key, n>>
*
* @return
*/
public List<Map.Entry<String, Integer>> getOrderList(Multimap<String, ThreadInfo> w_IdMap) {
Set<String> keys = w_IdMap.keySet();
Map<String, Integer> w_IdMappingThread = Maps.newHashMap();
for (String key : keys) {
Collection<ThreadInfo> values = w_IdMap.get(key);
w_IdMappingThread.put(key, values.size());
}
List<Map.Entry<String, Integer>> orderList =
new ArrayList<Map.Entry<String, Integer>>(w_IdMappingThread.entrySet());
Collections.sort(
orderList,
new Comparator<Map.Entry<String, Integer>>() {
@Override
public int compare(Map.Entry<String, Integer> o1, Map.Entry<String, Integer> o2) {
return o2.getValue().compareTo(o1.getValue());
}
});
return orderList;
}
/**
* Prepares a temporary attributes map for serialization purposes. Includes only the requested
* elements in the map.
*/
private Map<String, Object> prepareAttributesForSerialization(
boolean saveDocuments, boolean saveClusters, boolean saveOtherAttributes) {
final Map<String, Object> tempAttributes = Maps.newHashMap();
if (saveOtherAttributes) {
tempAttributes.putAll(attributes);
tempAttributes.remove(AttributeNames.DOCUMENTS);
tempAttributes.remove(AttributeNames.CLUSTERS);
} else {
tempAttributes.put(AttributeNames.QUERY, attributes.get(AttributeNames.QUERY));
}
if (saveDocuments) {
tempAttributes.put(AttributeNames.DOCUMENTS, getDocuments());
}
if (saveClusters) {
tempAttributes.put(AttributeNames.CLUSTERS, getClusters());
}
return tempAttributes;
}
@Override
public Map<String, Object> getValuesDeep() {
final Tag tag = this.findLastTag(this.path, false);
if (!(tag instanceof CompoundTag)) {
return Collections.emptyMap();
}
final Queue<Node> node =
new ArrayDeque<Node>(
(Collection<? extends Node>) ImmutableList.of((Object) new Node(tag)));
final Map<String, Object> values = (Map<String, Object>) Maps.newHashMap();
while (!node.isEmpty()) {
final Node root = node.poll();
for (final Map.Entry<String, Tag> entry : root.values.entrySet()) {
final String key = this.createRelativeKey(root.parent, entry.getKey());
if (entry.getValue() instanceof CompoundTag) {
node.add(new Node(key, entry.getValue()));
} else {
values.put(key, entry.getValue().getValue());
}
}
}
return values;
}
/** Transfers document and cluster lists to the attributes map after deserialization. */
@Commit
private void afterDeserialization() throws Exception {
if (otherAttributesForSerialization != null) {
attributes = SimpleXmlWrappers.unwrap(otherAttributesForSerialization);
}
attributesView = Collections.unmodifiableMap(attributes);
attributes.put(AttributeNames.QUERY, query != null ? query.trim() : null);
attributes.put(AttributeNames.DOCUMENTS, documents);
attributes.put(AttributeNames.CLUSTERS, clusters);
// Convert document ids to the actual references
if (clusters != null && documents != null) {
final Map<String, Document> documentsById = Maps.newHashMap();
for (Document document : documents) {
documentsById.put(document.getStringId(), document);
}
for (Cluster cluster : clusters) {
documentIdToReference(cluster, documentsById);
}
}
}
public class PseudocodeImpl implements Pseudocode {
public class PseudocodeLabel implements Label {
private final String name;
private final String comment;
private Integer targetInstructionIndex;
private PseudocodeLabel(@NotNull String name, @Nullable String comment) {
this.name = name;
this.comment = comment;
}
@NotNull
@Override
public String getName() {
return name;
}
@Override
public String toString() {
return comment == null ? name : (name + " [" + comment + "]");
}
public Integer getTargetInstructionIndex() {
return targetInstructionIndex;
}
public void setTargetInstructionIndex(int targetInstructionIndex) {
this.targetInstructionIndex = targetInstructionIndex;
}
@Nullable
private List<Instruction> resolve() {
assert targetInstructionIndex != null;
return mutableInstructionList.subList(
getTargetInstructionIndex(), mutableInstructionList.size());
}
public Instruction resolveToInstruction() {
assert targetInstructionIndex != null;
return mutableInstructionList.get(targetInstructionIndex);
}
public PseudocodeLabel copy(int newLabelIndex) {
return new PseudocodeLabel("L" + newLabelIndex, "copy of " + name + ", " + comment);
}
public PseudocodeImpl getPseudocode() {
return PseudocodeImpl.this;
}
}
private final List<Instruction> mutableInstructionList = new ArrayList<Instruction>();
private final List<Instruction> instructions = new ArrayList<Instruction>();
private final BidirectionalMap<KtElement, PseudoValue> elementsToValues =
new BidirectionalMap<KtElement, PseudoValue>();
private final Map<PseudoValue, List<Instruction>> valueUsages = Maps.newHashMap();
private final Map<PseudoValue, Set<PseudoValue>> mergedValues = Maps.newHashMap();
private final Set<Instruction> sideEffectFree = Sets.newHashSet();
private Pseudocode parent = null;
private Set<LocalFunctionDeclarationInstruction> localDeclarations = null;
// todo getters
private final Map<KtElement, Instruction> representativeInstructions =
new HashMap<KtElement, Instruction>();
private final List<PseudocodeLabel> labels = new ArrayList<PseudocodeLabel>();
private final KtElement correspondingElement;
private SubroutineExitInstruction exitInstruction;
private SubroutineSinkInstruction sinkInstruction;
private SubroutineExitInstruction errorInstruction;
private boolean postPrecessed = false;
public PseudocodeImpl(KtElement correspondingElement) {
this.correspondingElement = correspondingElement;
}
@NotNull
@Override
public KtElement getCorrespondingElement() {
return correspondingElement;
}
@NotNull
@Override
public Set<LocalFunctionDeclarationInstruction> getLocalDeclarations() {
if (localDeclarations == null) {
localDeclarations = getLocalDeclarations(this);
}
return localDeclarations;
}
@NotNull
private static Set<LocalFunctionDeclarationInstruction> getLocalDeclarations(
@NotNull Pseudocode pseudocode) {
Set<LocalFunctionDeclarationInstruction> localDeclarations = Sets.newLinkedHashSet();
for (Instruction instruction : ((PseudocodeImpl) pseudocode).mutableInstructionList) {
if (instruction instanceof LocalFunctionDeclarationInstruction) {
localDeclarations.add((LocalFunctionDeclarationInstruction) instruction);
localDeclarations.addAll(
getLocalDeclarations(((LocalFunctionDeclarationInstruction) instruction).getBody()));
}
}
return localDeclarations;
}
@Override
@Nullable
public Pseudocode getParent() {
return parent;
}
private void setParent(Pseudocode parent) {
this.parent = parent;
}
@NotNull
public Pseudocode getRootPseudocode() {
Pseudocode parent = getParent();
while (parent != null) {
if (parent.getParent() == null) return parent;
parent = parent.getParent();
}
return this;
}
/*package*/ PseudocodeLabel createLabel(@NotNull String name, @Nullable String comment) {
PseudocodeLabel label = new PseudocodeLabel(name, comment);
labels.add(label);
return label;
}
@Override
@NotNull
public List<Instruction> getInstructions() {
return instructions;
}
@NotNull
@Override
public List<Instruction> getReversedInstructions() {
LinkedHashSet<Instruction> traversedInstructions = Sets.newLinkedHashSet();
PseudocodeTraverserKt.traverseFollowingInstructions(
sinkInstruction, traversedInstructions, BACKWARD, null);
if (traversedInstructions.size() < instructions.size()) {
List<Instruction> simplyReversedInstructions = Lists.newArrayList(instructions);
Collections.reverse(simplyReversedInstructions);
for (Instruction instruction : simplyReversedInstructions) {
if (!traversedInstructions.contains(instruction)) {
PseudocodeTraverserKt.traverseFollowingInstructions(
instruction, traversedInstructions, BACKWARD, null);
}
}
}
return Lists.newArrayList(traversedInstructions);
}
@Override
@NotNull
public List<Instruction> getInstructionsIncludingDeadCode() {
return mutableInstructionList;
}
// for tests only
@NotNull
public List<PseudocodeLabel> getLabels() {
return labels;
}
/*package*/ void addExitInstruction(SubroutineExitInstruction exitInstruction) {
addInstruction(exitInstruction);
assert this.exitInstruction == null;
this.exitInstruction = exitInstruction;
}
/*package*/ void addSinkInstruction(SubroutineSinkInstruction sinkInstruction) {
addInstruction(sinkInstruction);
assert this.sinkInstruction == null;
this.sinkInstruction = sinkInstruction;
}
/*package*/ void addErrorInstruction(SubroutineExitInstruction errorInstruction) {
addInstruction(errorInstruction);
assert this.errorInstruction == null;
this.errorInstruction = errorInstruction;
}
/*package*/ void addInstruction(Instruction instruction) {
mutableInstructionList.add(instruction);
instruction.setOwner(this);
if (instruction instanceof KtElementInstruction) {
KtElementInstruction elementInstruction = (KtElementInstruction) instruction;
representativeInstructions.put(elementInstruction.getElement(), instruction);
}
if (instruction instanceof MergeInstruction) {
addMergedValues((MergeInstruction) instruction);
}
for (PseudoValue inputValue : instruction.getInputValues()) {
addValueUsage(inputValue, instruction);
for (PseudoValue mergedValue : getMergedValues(inputValue)) {
addValueUsage(mergedValue, instruction);
}
}
if (PseudocodeUtilsKt.calcSideEffectFree(instruction)) {
sideEffectFree.add(instruction);
}
}
@Override
@NotNull
public SubroutineExitInstruction getExitInstruction() {
return exitInstruction;
}
@Override
@NotNull
public SubroutineSinkInstruction getSinkInstruction() {
return sinkInstruction;
}
@Override
@NotNull
public SubroutineEnterInstruction getEnterInstruction() {
return (SubroutineEnterInstruction) mutableInstructionList.get(0);
}
@Nullable
@Override
public PseudoValue getElementValue(@Nullable KtElement element) {
return elementsToValues.get(element);
}
@NotNull
@Override
public List<? extends KtElement> getValueElements(@Nullable PseudoValue value) {
List<? extends KtElement> result = elementsToValues.getKeysByValue(value);
return result != null ? result : Collections.<KtElement>emptyList();
}
@NotNull
@Override
public List<? extends Instruction> getUsages(@Nullable PseudoValue value) {
List<? extends Instruction> result = valueUsages.get(value);
return result != null ? result : Collections.<Instruction>emptyList();
}
@Override
public boolean isSideEffectFree(@NotNull Instruction instruction) {
return sideEffectFree.contains(instruction);
}
/*package*/ void bindElementToValue(@NotNull KtElement element, @NotNull PseudoValue value) {
elementsToValues.put(element, value);
}
/*package*/ void bindLabel(Label label) {
((PseudocodeLabel) label).setTargetInstructionIndex(mutableInstructionList.size());
}
private Set<PseudoValue> getMergedValues(@NotNull PseudoValue value) {
Set<PseudoValue> result = mergedValues.get(value);
return result != null ? result : Collections.<PseudoValue>emptySet();
}
private void addMergedValues(@NotNull MergeInstruction instruction) {
Set<PseudoValue> result = new LinkedHashSet<PseudoValue>();
for (PseudoValue value : instruction.getInputValues()) {
result.addAll(getMergedValues(value));
result.add(value);
}
mergedValues.put(instruction.getOutputValue(), result);
}
private void addValueUsage(PseudoValue value, Instruction usage) {
if (usage instanceof MergeInstruction) return;
MapsKt.getOrPut(
valueUsages,
value,
new Function0<List<Instruction>>() {
@Override
public List<Instruction> invoke() {
return Lists.newArrayList();
}
})
.add(usage);
}
public void postProcess() {
if (postPrecessed) return;
postPrecessed = true;
errorInstruction.setSink(getSinkInstruction());
exitInstruction.setSink(getSinkInstruction());
int index = 0;
for (Instruction instruction : mutableInstructionList) {
// recursively invokes 'postProcess' for local declarations
processInstruction(instruction, index);
index++;
}
if (getParent() != null) return;
// Collecting reachable instructions should be done after processing all instructions
// (including instructions in local declarations) to avoid being in incomplete state.
collectAndCacheReachableInstructions();
for (LocalFunctionDeclarationInstruction localFunctionDeclarationInstruction :
getLocalDeclarations()) {
((PseudocodeImpl) localFunctionDeclarationInstruction.getBody())
.collectAndCacheReachableInstructions();
}
}
private void collectAndCacheReachableInstructions() {
Set<Instruction> reachableInstructions = collectReachableInstructions();
for (Instruction instruction : mutableInstructionList) {
if (reachableInstructions.contains(instruction)) {
instructions.add(instruction);
}
}
markDeadInstructions();
}
private void processInstruction(Instruction instruction, final int currentPosition) {
instruction.accept(
new InstructionVisitor() {
@Override
public void visitInstructionWithNext(@NotNull InstructionWithNext instruction) {
instruction.setNext(getNextPosition(currentPosition));
}
@Override
public void visitJump(@NotNull AbstractJumpInstruction instruction) {
instruction.setResolvedTarget(getJumpTarget(instruction.getTargetLabel()));
}
@Override
public void visitNondeterministicJump(
@NotNull NondeterministicJumpInstruction instruction) {
instruction.setNext(getNextPosition(currentPosition));
List<Label> targetLabels = instruction.getTargetLabels();
for (Label targetLabel : targetLabels) {
instruction.setResolvedTarget(targetLabel, getJumpTarget(targetLabel));
}
}
@Override
public void visitConditionalJump(@NotNull ConditionalJumpInstruction instruction) {
Instruction nextInstruction = getNextPosition(currentPosition);
Instruction jumpTarget = getJumpTarget(instruction.getTargetLabel());
if (instruction.getOnTrue()) {
instruction.setNextOnFalse(nextInstruction);
instruction.setNextOnTrue(jumpTarget);
} else {
instruction.setNextOnFalse(jumpTarget);
instruction.setNextOnTrue(nextInstruction);
}
visitJump(instruction);
}
@Override
public void visitLocalFunctionDeclarationInstruction(
@NotNull LocalFunctionDeclarationInstruction instruction) {
PseudocodeImpl body = (PseudocodeImpl) instruction.getBody();
body.setParent(PseudocodeImpl.this);
body.postProcess();
instruction.setNext(getSinkInstruction());
}
@Override
public void visitSubroutineExit(@NotNull SubroutineExitInstruction instruction) {
// Nothing
}
@Override
public void visitSubroutineSink(@NotNull SubroutineSinkInstruction instruction) {
// Nothing
}
@Override
public void visitInstruction(@NotNull Instruction instruction) {
throw new UnsupportedOperationException(instruction.toString());
}
});
}
private Set<Instruction> collectReachableInstructions() {
Set<Instruction> visited = Sets.newHashSet();
PseudocodeTraverserKt.traverseFollowingInstructions(
getEnterInstruction(), visited, FORWARD, null);
if (!visited.contains(getExitInstruction())) {
visited.add(getExitInstruction());
}
if (!visited.contains(errorInstruction)) {
visited.add(errorInstruction);
}
if (!visited.contains(getSinkInstruction())) {
visited.add(getSinkInstruction());
}
return visited;
}
private void markDeadInstructions() {
Set<Instruction> instructionSet = Sets.newHashSet(instructions);
for (Instruction instruction : mutableInstructionList) {
if (!instructionSet.contains(instruction)) {
((InstructionImpl) instruction).setMarkedAsDead(true);
for (Instruction nextInstruction : instruction.getNextInstructions()) {
nextInstruction.getPreviousInstructions().remove(instruction);
}
}
}
}
@NotNull
private Instruction getJumpTarget(@NotNull Label targetLabel) {
return ((PseudocodeLabel) targetLabel).resolveToInstruction();
}
@NotNull
private Instruction getNextPosition(int currentPosition) {
int targetPosition = currentPosition + 1;
assert targetPosition < mutableInstructionList.size() : currentPosition;
return mutableInstructionList.get(targetPosition);
}
@Override
public PseudocodeImpl copy() {
PseudocodeImpl result = new PseudocodeImpl(correspondingElement);
result.repeatWhole(this);
return result;
}
private void repeatWhole(@NotNull PseudocodeImpl originalPseudocode) {
repeatInternal(originalPseudocode, null, null, 0);
parent = originalPseudocode.parent;
}
public int repeatPart(@NotNull Label startLabel, @NotNull Label finishLabel, int labelCount) {
return repeatInternal(
((PseudocodeLabel) startLabel).getPseudocode(), startLabel, finishLabel, labelCount);
}
private int repeatInternal(
@NotNull PseudocodeImpl originalPseudocode,
@Nullable Label startLabel,
@Nullable Label finishLabel,
int labelCount) {
Integer startIndex =
startLabel != null
? ((PseudocodeLabel) startLabel).getTargetInstructionIndex()
: Integer.valueOf(0);
assert startIndex != null;
Integer finishIndex =
finishLabel != null
? ((PseudocodeLabel) finishLabel).getTargetInstructionIndex()
: Integer.valueOf(originalPseudocode.mutableInstructionList.size());
assert finishIndex != null;
Map<Label, Label> originalToCopy = Maps.newLinkedHashMap();
Multimap<Instruction, Label> originalLabelsForInstruction = HashMultimap.create();
for (PseudocodeLabel label : originalPseudocode.labels) {
Integer index = label.getTargetInstructionIndex();
if (index == null) continue; // label is not bounded yet
if (label == startLabel || label == finishLabel) continue;
if (startIndex <= index && index <= finishIndex) {
originalToCopy.put(label, label.copy(labelCount++));
originalLabelsForInstruction.put(getJumpTarget(label), label);
}
}
for (Label label : originalToCopy.values()) {
labels.add((PseudocodeLabel) label);
}
for (int index = startIndex; index < finishIndex; index++) {
Instruction originalInstruction = originalPseudocode.mutableInstructionList.get(index);
repeatLabelsBindingForInstruction(
originalInstruction, originalToCopy, originalLabelsForInstruction);
Instruction copy = copyInstruction(originalInstruction, originalToCopy);
addInstruction(copy);
if (originalInstruction == originalPseudocode.errorInstruction
&& copy instanceof SubroutineExitInstruction) {
errorInstruction = (SubroutineExitInstruction) copy;
}
if (originalInstruction == originalPseudocode.exitInstruction
&& copy instanceof SubroutineExitInstruction) {
exitInstruction = (SubroutineExitInstruction) copy;
}
if (originalInstruction == originalPseudocode.sinkInstruction
&& copy instanceof SubroutineSinkInstruction) {
sinkInstruction = (SubroutineSinkInstruction) copy;
}
}
if (finishIndex < mutableInstructionList.size()) {
repeatLabelsBindingForInstruction(
originalPseudocode.mutableInstructionList.get(finishIndex),
originalToCopy,
originalLabelsForInstruction);
}
return labelCount;
}
private void repeatLabelsBindingForInstruction(
@NotNull Instruction originalInstruction,
@NotNull Map<Label, Label> originalToCopy,
@NotNull Multimap<Instruction, Label> originalLabelsForInstruction) {
for (Label originalLabel : originalLabelsForInstruction.get(originalInstruction)) {
bindLabel(originalToCopy.get(originalLabel));
}
}
private static Instruction copyInstruction(
@NotNull Instruction instruction, @NotNull Map<Label, Label> originalToCopy) {
if (instruction instanceof AbstractJumpInstruction) {
Label originalTarget = ((AbstractJumpInstruction) instruction).getTargetLabel();
if (originalToCopy.containsKey(originalTarget)) {
return ((AbstractJumpInstruction) instruction).copy(originalToCopy.get(originalTarget));
}
}
if (instruction instanceof NondeterministicJumpInstruction) {
List<Label> originalTargets =
((NondeterministicJumpInstruction) instruction).getTargetLabels();
List<Label> copyTargets = copyLabels(originalTargets, originalToCopy);
return ((NondeterministicJumpInstruction) instruction).copy(copyTargets);
}
return ((InstructionImpl) instruction).copy();
}
@NotNull
private static List<Label> copyLabels(
Collection<Label> labels, Map<Label, Label> originalToCopy) {
List<Label> newLabels = Lists.newArrayList();
for (Label label : labels) {
Label newLabel = originalToCopy.get(label);
newLabels.add(newLabel != null ? newLabel : label);
}
return newLabels;
}
}
/**
* Represents one network of nodes, where each nodes is somehow connected to another within the
* network.
*
* <p>Network contains following node types: - networking nodes - nodes that are a back-bone of a
* network. These allow to connect multiple nodes in the network. A networking node "conducts" the
* "signal" of the network to nodes defined in the "connectingOnSides" nodes in its vicinity. - leaf
* nodes - nodes that are only receiving or producing a signal, and do not themselves "conduct" it
* to other nodes.
*
* <p>A couple of non-obvious facts: 1. The same node (defined as location) cannot be both a
* networking node and a leaf node in the same network. 2. The same leaf node can be a member of
* multiple disjunctive networks (different network on each side). 3. A valid network can have no
* networking nodes at all, and exactly two leaf nodes (neighbouring leaf nodes).
*
* @author Marcin Sciesinski <*****@*****.**>
*/
public class SimpleNetwork implements Network {
private static final boolean SANITY_CHECK = false;
private SetMultimap<ImmutableBlockLocation, NetworkNode> networkingNodes = HashMultimap.create();
private SetMultimap<ImmutableBlockLocation, NetworkNode> leafNodes = HashMultimap.create();
// Distance cache
private Map<TwoNetworkNodes, Integer> distanceCache = Maps.newHashMap();
public static SimpleNetwork createDegenerateNetwork(
NetworkNode networkNode1, NetworkNode networkNode2) {
if (!areNodesConnecting(networkNode1, networkNode2))
throw new IllegalArgumentException("These two nodes are not connected");
SimpleNetwork network = new SimpleNetwork();
network.leafNodes.put(networkNode1.location, networkNode1);
network.leafNodes.put(networkNode2.location, networkNode2);
return network;
}
/**
* Adds a networking node to the network.
*
* @param networkNode Definition of the networking node position and connecting sides.
*/
public void addNetworkingNode(NetworkNode networkNode) {
if (SANITY_CHECK && !canAddNetworkingNode(networkNode))
throw new IllegalStateException("Unable to add this node to network");
networkingNodes.put(networkNode.location, networkNode);
distanceCache.clear();
}
/**
* Adds a leaf node to the network.
*
* @param networkNode Definition of the leaf node position and connecting sides.
*/
public void addLeafNode(NetworkNode networkNode) {
if (SANITY_CHECK && (!canAddLeafNode(networkNode) || isEmptyNetwork()))
throw new IllegalStateException("Unable to add this node to network");
leafNodes.put(networkNode.location, networkNode);
distanceCache.clear();
}
/**
* Returns the network size - a number of nodes it spans. If the same node is added twice with
* different connecting sides, it is counted twice.
*
* @return The sum of networking nodes and leaf nodes (count).
*/
@Override
public int getNetworkSize() {
return networkingNodes.size() + leafNodes.size();
}
/**
* Removes a leaf node from the network. If this removal made the network degenerate, it will
* return <code>true</code>.
*
* @param networkingNode Definition of the leaf node position and connecting sides.
* @return <code>true</code> if the network after the removal is degenerated or empty (no longer
* valid).
*/
public boolean removeLeafNode(NetworkNode networkingNode) {
// Removal of a leaf node cannot split the network, so it's just safe to remove it
// We just need to check, if after removal of the node, network becomes degenerated, if so - we
// need
// to signal that the network is no longer valid and should be removed.
final boolean changed = leafNodes.remove(networkingNode.location, networkingNode);
if (!changed)
throw new IllegalStateException("Tried to remove a node that is not in the network");
distanceCache.clear();
return isDegeneratedNetwork() || isEmptyNetwork();
}
public void removeAllLeafNodes() {
leafNodes.clear();
distanceCache.clear();
}
public void removeAllNetworkingNodes() {
networkingNodes.clear();
distanceCache.clear();
}
public void removeNetworkingNode(NetworkNode networkNode) {
if (!networkingNodes.remove(networkNode.location, networkNode))
throw new IllegalStateException("Tried to remove a node that is not in the network");
distanceCache.clear();
}
public Collection<NetworkNode> getNetworkingNodes() {
return Collections.unmodifiableCollection(networkingNodes.values());
}
public Collection<NetworkNode> getLeafNodes() {
return Collections.unmodifiableCollection(leafNodes.values());
}
public static boolean areNodesConnecting(NetworkNode node1, NetworkNode node2) {
for (Side side : SideBitFlag.getSides(node1.connectionSides)) {
final ImmutableBlockLocation possibleConnectedLocation = node1.location.move(side);
if (node2.location.equals(possibleConnectedLocation)
&& SideBitFlag.hasSide(node2.connectionSides, side.reverse())) return true;
}
return false;
}
/**
* If this network can connect to node at the location specified with the specified connecting
* sides.
*
* @param networkNode Definition of the networking node position and connecting sides.
* @return If the networking node can be added to the network (connects to it).
*/
public boolean canAddNetworkingNode(NetworkNode networkNode) {
if (isEmptyNetwork()) return true;
if (networkingNodes.containsValue(networkNode) || leafNodes.containsValue(networkNode))
return false;
return canConnectToNetworkingNode(networkNode);
}
public boolean canAddLeafNode(NetworkNode networkNode) {
if (isEmptyNetwork()) return false;
if (networkingNodes.containsValue(networkNode) || leafNodes.containsValue(networkNode))
return false;
return canConnectToNetworkingNode(networkNode);
}
private boolean canConnectToNetworkingNode(NetworkNode networkNode) {
for (Side connectingOnSide : SideBitFlag.getSides(networkNode.connectionSides)) {
final ImmutableBlockLocation possibleConnectionLocation =
networkNode.location.move(connectingOnSide);
for (NetworkNode possibleConnectedNode : networkingNodes.get(possibleConnectionLocation)) {
if (SideBitFlag.hasSide(possibleConnectedNode.connectionSides, connectingOnSide.reverse()))
return true;
}
}
return false;
}
@Override
public boolean hasNetworkingNode(NetworkNode networkNode) {
return networkingNodes.containsValue(networkNode);
}
@Override
public boolean hasLeafNode(NetworkNode networkNode) {
return leafNodes.containsValue(networkNode);
}
@Override
public int getDistance(NetworkNode from, NetworkNode to) {
TwoNetworkNodes nodePair = new TwoNetworkNodes(from, to);
final Integer cachedDistance = distanceCache.get(nodePair);
if (cachedDistance != null) return cachedDistance;
if ((!hasNetworkingNode(from) && !hasLeafNode(from))
|| (!hasNetworkingNode(to) && !hasLeafNode(to)))
throw new IllegalArgumentException("Cannot test nodes not in network");
if (from.equals(to)) return 0;
if (SimpleNetwork.areNodesConnecting(from, to)) return 1;
// Breadth-first search of the network
Set<NetworkNode> visitedNodes = Sets.newHashSet();
visitedNodes.add(from);
Set<NetworkNode> networkingNodesToTest = Sets.newHashSet();
listConnectedNotVisitedNetworkingNodes(visitedNodes, from, networkingNodesToTest);
int distanceSearched = 1;
while (networkingNodesToTest.size() > 0) {
distanceSearched++;
for (NetworkNode nodeToTest : networkingNodesToTest) {
if (SimpleNetwork.areNodesConnecting(nodeToTest, to)) {
distanceCache.put(new TwoNetworkNodes(from, to), distanceSearched);
return distanceSearched;
}
visitedNodes.add(nodeToTest);
}
Set<NetworkNode> nextNetworkingNodesToTest = Sets.newHashSet();
for (NetworkNode nodeToTest : networkingNodesToTest)
listConnectedNotVisitedNetworkingNodes(visitedNodes, nodeToTest, nextNetworkingNodesToTest);
networkingNodesToTest = nextNetworkingNodesToTest;
}
return -1;
}
@Override
public boolean isInDistance(int distance, NetworkNode from, NetworkNode to) {
if (distance < 0) throw new IllegalArgumentException("distance must be >= 0");
TwoNetworkNodes nodePair = new TwoNetworkNodes(from, to);
final Integer cachedDistance = distanceCache.get(nodePair);
if (cachedDistance != null) return cachedDistance <= distance;
if ((!hasNetworkingNode(from) && !hasLeafNode(from))
|| (!hasNetworkingNode(to) && !hasLeafNode(to)))
throw new IllegalArgumentException("Cannot test nodes not in network");
return isInDistanceInternal(distance, from, to, nodePair);
}
private boolean isInDistanceInternal(
int distance, NetworkNode from, NetworkNode to, TwoNetworkNodes cachePairKey) {
if (from.equals(to)) return true;
if (distance == 0) return false;
if (SimpleNetwork.areNodesConnecting(from, to)) return true;
// Breadth-first search of the network
Set<NetworkNode> visitedNodes = Sets.newHashSet();
visitedNodes.add(from);
Set<NetworkNode> networkingNodesToTest = Sets.newHashSet();
listConnectedNotVisitedNetworkingNodes(visitedNodes, from, networkingNodesToTest);
int distanceSearched = 1;
while (distanceSearched < distance) {
distanceSearched++;
for (NetworkNode nodeToTest : networkingNodesToTest) {
if (SimpleNetwork.areNodesConnecting(nodeToTest, to)) {
distanceCache.put(cachePairKey, distanceSearched);
return true;
}
visitedNodes.add(nodeToTest);
}
Set<NetworkNode> nextNetworkingNodesToTest = Sets.newHashSet();
for (NetworkNode nodeToTest : networkingNodesToTest)
listConnectedNotVisitedNetworkingNodes(visitedNodes, nodeToTest, nextNetworkingNodesToTest);
networkingNodesToTest = nextNetworkingNodesToTest;
}
return false;
}
@Override
public boolean isInDistanceWithSide(int distance, NetworkNode from, NetworkNode to, Side toSide) {
to = new NetworkNode(to.location.toVector3i(), toSide);
TwoNetworkNodes nodePair = new TwoNetworkNodes(from, to);
return isInDistanceInternal(distance, from, to, nodePair);
}
@Override
public byte getLeafSidesInNetwork(NetworkNode networkNode) {
if (!hasLeafNode(networkNode))
throw new IllegalArgumentException("Cannot test nodes not in network");
if (networkingNodes.size() == 0) {
// Degenerated network
for (Side connectingOnSide : SideBitFlag.getSides(networkNode.connectionSides)) {
Vector3i possibleLocation = networkNode.location.toVector3i();
possibleLocation.add(connectingOnSide.getVector3i());
for (NetworkNode node : leafNodes.get(new ImmutableBlockLocation(possibleLocation))) {
if (SideBitFlag.hasSide(node.connectionSides, connectingOnSide.reverse())) {
return SideBitFlag.getSide(connectingOnSide);
}
}
}
return 0;
} else {
byte result = 0;
for (Side connectingOnSide : SideBitFlag.getSides(networkNode.connectionSides)) {
Vector3i possibleLocation = networkNode.location.toVector3i();
possibleLocation.add(connectingOnSide.getVector3i());
for (NetworkNode node : networkingNodes.get(new ImmutableBlockLocation(possibleLocation))) {
if (SideBitFlag.hasSide(node.connectionSides, connectingOnSide.reverse())) {
result += SideBitFlag.getSide(connectingOnSide);
}
}
}
return result;
}
}
// public Map<Vector3i, Byte> getConnectedNodes(Vector3i location, byte connectionSides) {
// Map<Vector3i, Byte> result = Maps.newHashMap();
// for (Direction connectingOnSide : DirectionsUtil.getDirections(connectionSides)) {
// final Vector3i possibleNodeLocation = new Vector3i(location);
// possibleNodeLocation.add(connectingOnSide.getVector3i());
//
// final Byte directionsForNodeOnThatSide = networkingNodes.get(possibleNodeLocation);
// if (directionsForNodeOnThatSide != null &&
// DirectionsUtil.hasDirection(directionsForNodeOnThatSide, connectingOnSide.reverse()))
// result.put(possibleNodeLocation, directionsForNodeOnThatSide);
//
// for (byte directionsForLeafNodeOnThatSide : leafNodes.get(possibleNodeLocation)) {
// if (DirectionsUtil.hasDirection(directionsForLeafNodeOnThatSide,
// connectingOnSide.reverse()))
// result.put(possibleNodeLocation, directionsForLeafNodeOnThatSide);
// }
// }
// return result;
// }
private void listConnectedNotVisitedNetworkingNodes(
Set<NetworkNode> visitedNodes, NetworkNode location, Collection<NetworkNode> result) {
for (Side connectingOnSide : SideBitFlag.getSides(location.connectionSides)) {
final ImmutableBlockLocation possibleConnectionLocation =
location.location.move(connectingOnSide);
for (NetworkNode possibleConnection : networkingNodes.get(possibleConnectionLocation)) {
if (!visitedNodes.contains(possibleConnection)
&& SideBitFlag.hasSide(possibleConnection.connectionSides, connectingOnSide.reverse()))
result.add(possibleConnection);
}
}
}
private boolean isDegeneratedNetwork() {
return networkingNodes.isEmpty() && leafNodes.size() == 1;
}
private boolean isEmptyNetwork() {
return networkingNodes.isEmpty() && leafNodes.isEmpty();
}
}
/** For JSON and XML serialization only. */
@JsonProperty("attributes")
@SuppressWarnings("unused")
private Map<String, Object> getOtherAttributes() {
final Map<String, Object> otherAttributes = Maps.newHashMap(attributesView);
return otherAttributes.isEmpty() ? null : otherAttributes;
}
/**
* Parse the given array of arguments.
*
* <p>Empty arguments are removed from the list of arguments.
*
* @param args an array with arguments
* @param expectedValueFlags a set containing all value flags (pass null to disable value flag
* parsing)
* @param allowHangingFlag true if hanging flags are allowed
* @param namespace the locals, null to create empty one
* @throws CommandException thrown on a parsing error
*/
public CommandContext(
String[] args,
Set<Character> expectedValueFlags,
boolean allowHangingFlag,
Namespace namespace)
throws CommandException {
if (expectedValueFlags == null) {
expectedValueFlags = Collections.emptySet();
}
originalArgs = args;
command = args[0];
this.namespace = namespace != null ? namespace : new Namespace();
boolean isHanging = false;
SuggestionContext suggestionContext = SuggestionContext.hangingValue();
// Eliminate empty args and combine multiword args first
List<Integer> argIndexList = new ArrayList<Integer>(args.length);
List<String> argList = new ArrayList<String>(args.length);
for (int i = 1; i < args.length; ++i) {
isHanging = false;
String arg = args[i];
if (arg.isEmpty()) {
isHanging = true;
continue;
}
argIndexList.add(i);
switch (arg.charAt(0)) {
case '\'':
case '"':
final StringBuilder build = new StringBuilder();
final char quotedChar = arg.charAt(0);
int endIndex;
for (endIndex = i; endIndex < args.length; ++endIndex) {
final String arg2 = args[endIndex];
if (arg2.charAt(arg2.length() - 1) == quotedChar && arg2.length() > 1) {
if (endIndex != i) build.append(' ');
build.append(arg2.substring(endIndex == i ? 1 : 0, arg2.length() - 1));
break;
} else if (endIndex == i) {
build.append(arg2.substring(1));
} else {
build.append(' ').append(arg2);
}
}
if (endIndex < args.length) {
arg = build.toString();
i = endIndex;
}
// In case there is an empty quoted string
if (arg.isEmpty()) {
continue;
}
// else raise exception about hanging quotes?
}
argList.add(arg);
}
// Then flags
List<Integer> originalArgIndices = Lists.newArrayListWithCapacity(argIndexList.size());
List<String> parsedArgs = Lists.newArrayListWithCapacity(argList.size());
Map<Character, String> valueFlags = Maps.newHashMap();
List<Character> booleanFlags = Lists.newArrayList();
for (int nextArg = 0; nextArg < argList.size(); ) {
// Fetch argument
String arg = argList.get(nextArg++);
suggestionContext = SuggestionContext.hangingValue();
// Not a flag?
if (arg.charAt(0) != '-' || arg.length() == 1 || !arg.matches("^-[a-zA-Z\\?]+$")) {
if (!isHanging) {
suggestionContext = SuggestionContext.lastValue();
}
originalArgIndices.add(argIndexList.get(nextArg - 1));
parsedArgs.add(arg);
continue;
}
// Handle flag parsing terminator --
if (arg.equals("--")) {
while (nextArg < argList.size()) {
originalArgIndices.add(argIndexList.get(nextArg));
parsedArgs.add(argList.get(nextArg++));
}
break;
}
// Go through the flag characters
for (int i = 1; i < arg.length(); ++i) {
char flagName = arg.charAt(i);
if (expectedValueFlags.contains(flagName)) {
if (valueFlags.containsKey(flagName)) {
throw new CommandException("Value flag '" + flagName + "' already given");
}
if (nextArg >= argList.size()) {
if (allowHangingFlag) {
suggestionContext = SuggestionContext.flag(flagName);
break;
} else {
throw new CommandException("No value specified for the '-" + flagName + "' flag.");
}
}
// If it is a value flag, read another argument and add it
valueFlags.put(flagName, argList.get(nextArg++));
if (!isHanging) {
suggestionContext = SuggestionContext.flag(flagName);
}
} else {
booleanFlags.add(flagName);
}
}
}
ImmutableMap.Builder<Character, String> allFlagsBuilder =
new ImmutableMap.Builder<Character, String>().putAll(valueFlags);
for (Character flag : booleanFlags) {
allFlagsBuilder.put(flag, "true");
}
this.parsedArgs = ImmutableList.copyOf(parsedArgs);
this.originalArgIndices = ImmutableList.copyOf(originalArgIndices);
this.booleanFlags = ImmutableSet.copyOf(booleanFlags);
this.valueFlags = ImmutableMap.copyOf(valueFlags);
this.allFlags = allFlagsBuilder.build();
this.suggestionContext = suggestionContext;
}
/**
* Encapsulates the results of processing. Provides access to the values of attributes collected
* after processing and utility methods for obtaining processed documents ( {@link
* #getDocuments()})) and the created clusters ({@link #getClusters()}).
*/
@Root(name = "searchresult", strict = false)
public final class ProcessingResult {
/** Attributes collected after processing */
private Map<String, Object> attributes = Maps.newHashMap();
/** Read-only view of attributes exposed in {@link #getAttributes()} */
private Map<String, Object> attributesView;
/**
* Query field used during serialization/ deserialization, see {@link #afterDeserialization()} and
* {@link #beforeSerialization()}
*/
@Element(required = false)
private String query;
/**
* Documents field used during serialization/ deserialization, see {@link #afterDeserialization()}
* and {@link #beforeSerialization()}
*/
@ElementList(inline = true, required = false)
private List<Document> documents;
/**
* Clusters field used during serialization/ deserialization, see {@link #afterDeserialization()}
* and {@link #beforeSerialization()}
*/
@ElementList(inline = true, required = false)
private List<Cluster> clusters;
/** Attributes of this result for serialization/ deserialization purposes. */
@ElementMap(entry = "attribute", key = "key", attribute = true, inline = true, required = false)
private HashMap<String, SimpleXmlWrapperValue> otherAttributesForSerialization;
/** Parameterless constructor required for XML serialization/ deserialization. */
ProcessingResult() {
this(new HashMap<String, Object>());
}
/**
* Creates a {@link ProcessingResult} with the provided <code>attributes</code>. Assigns unique
* document identifiers if documents are present in the <code>attributes</code> map (under the key
* {@link AttributeNames#DOCUMENTS}).
*/
@SuppressWarnings("unchecked")
ProcessingResult(Map<String, Object> attributes) {
this.attributes = attributes;
// Replace a modifiable collection of documents with an unmodifiable one
final List<Document> documents = (List<Document>) attributes.get(AttributeNames.DOCUMENTS);
if (documents != null) {
Document.assignDocumentIds(documents);
attributes.put(AttributeNames.DOCUMENTS, Collections.unmodifiableList(documents));
}
// Replace a modifiable collection of clusters with an unmodifiable one
final List<Cluster> clusters = (List<Cluster>) attributes.get(AttributeNames.CLUSTERS);
if (clusters != null) {
Cluster.assignClusterIds(clusters);
attributes.put(AttributeNames.CLUSTERS, Collections.unmodifiableList(clusters));
}
// Store a reference to attributes as an unmodifiable map
this.attributesView = Collections.unmodifiableMap(attributes);
}
/**
* Returns attributes fed-in and collected during processing. The returned map is unmodifiable.
*
* @return attributes fed-in and collected during processing
*/
public Map<String, Object> getAttributes() {
return attributesView;
}
/**
* Returns a specific attribute of this result set. This method is equivalent to calling {@link
* #getAttributes()} and then getting the required attribute from the map.
*
* @param key key of the attribute to return
* @return value of the attribute
*/
@SuppressWarnings("unchecked")
public <T> T getAttribute(String key) {
return (T) attributesView.get(key);
}
/**
* Returns the documents that have been processed. The returned collection is unmodifiable.
*
* @return documents that have been processed or <code>null</code> if no documents are present in
* the result.
*/
@SuppressWarnings("unchecked")
public List<Document> getDocuments() {
return (List<Document>) attributes.get(AttributeNames.DOCUMENTS);
}
/*
* TODO: Returning a list of clusters instead of a (possibly artificial) cluster with
* subclusters adds a little complexity to recursive methods operating on clusters (a
* natural entry point is a method taking one cluster and acting on subclusters
* recursively). If we have to start with a list of clusters, we have to handle this
* special case separately...
*/
/**
* Returns the clusters that have been created during processing. The returned list is
* unmodifiable.
*
* @return clusters created during processing or <code>null</code> if no clusters were present in
* the result.
*/
@SuppressWarnings("unchecked")
public List<Cluster> getClusters() {
return (List<Cluster>) attributes.get(AttributeNames.CLUSTERS);
}
/** Extracts document and cluster lists before serialization. */
@Persist
private void beforeSerialization() {
/*
* See http://issues.carrot2.org/browse/CARROT-693; this monitor does not save us
* in multi-threaded environment anyway. A better solution would be to prepare
* this eagerly in the constructor, but we try to balance overhead and full
* correctness here.
*/
synchronized (this) {
query = (String) attributes.get(AttributeNames.QUERY);
if (getDocuments() != null) {
documents = Lists.newArrayList(getDocuments());
} else {
documents = null;
}
if (getClusters() != null) {
clusters = Lists.newArrayList(getClusters());
} else {
clusters = null;
}
otherAttributesForSerialization = MapUtils.asHashMap(SimpleXmlWrappers.wrap(attributes));
otherAttributesForSerialization.remove(AttributeNames.QUERY);
otherAttributesForSerialization.remove(AttributeNames.CLUSTERS);
otherAttributesForSerialization.remove(AttributeNames.DOCUMENTS);
if (otherAttributesForSerialization.isEmpty()) {
otherAttributesForSerialization = null;
}
}
}
/** Transfers document and cluster lists to the attributes map after deserialization. */
@Commit
private void afterDeserialization() throws Exception {
if (otherAttributesForSerialization != null) {
attributes = SimpleXmlWrappers.unwrap(otherAttributesForSerialization);
}
attributesView = Collections.unmodifiableMap(attributes);
attributes.put(AttributeNames.QUERY, query != null ? query.trim() : null);
attributes.put(AttributeNames.DOCUMENTS, documents);
attributes.put(AttributeNames.CLUSTERS, clusters);
// Convert document ids to the actual references
if (clusters != null && documents != null) {
final Map<String, Document> documentsById = Maps.newHashMap();
for (Document document : documents) {
documentsById.put(document.getStringId(), document);
}
for (Cluster cluster : clusters) {
documentIdToReference(cluster, documentsById);
}
}
}
/** Replace document refids with the actual references upon deserialization. */
private void documentIdToReference(Cluster cluster, Map<String, Document> documents) {
if (cluster.documentIds != null) {
for (Cluster.DocumentRefid documentRefid : cluster.documentIds) {
cluster.addDocuments(documents.get(documentRefid.refid));
}
}
for (Cluster subcluster : cluster.getSubclusters()) {
documentIdToReference(subcluster, documents);
}
}
/** Serializes this {@link ProcessingResult} to an XML string. */
public String serialize() {
try {
StringWriter sw = new StringWriter();
new Persister().write(this, sw);
return sw.toString();
} catch (Exception e) {
throw new RuntimeException(e);
}
}
/**
* Serializes this {@link ProcessingResult} to an XML stream. The output includes all documents,
* clusters and other attributes.
*
* <p>This method is not thread-safe, external synchronization must be applied if needed.
*
* @param stream the stream to serialize this {@link ProcessingResult} to. The stream will
* <strong>not</strong> be closed.
* @throws Exception in case of any problems with serialization
*/
public void serialize(OutputStream stream) throws Exception {
serialize(stream, true, true);
}
/**
* Serializes this {@link ProcessingResult} to a byte stream. Documents and clusters can be
* included or skipped in the output as requested. Other attributes are always included.
*
* <p>This method is not thread-safe, external synchronization must be applied if needed.
*
* @param stream the stream to serialize this {@link ProcessingResult} to. The stream will
* <strong>not</strong> be closed.
* @param saveDocuments if <code>false</code>, documents will not be serialized. Notice that when
* deserializing XML containing clusters but not documents, document references in {@link
* Cluster#getDocuments()} will not be restored.
* @param saveClusters if <code>false</code>, clusters will not be serialized
* @throws Exception in case of any problems with serialization
*/
public void serialize(OutputStream stream, boolean saveDocuments, boolean saveClusters)
throws Exception {
serialize(stream, saveDocuments, saveClusters, true);
}
/**
* Serializes this {@link ProcessingResult} to a byte stream. Documents, clusters and other
* attributes can be included or skipped in the output as requested.
*
* <p>This method is not thread-safe, external synchronization must be applied if needed.
*
* @param stream the stream to serialize this {@link ProcessingResult} to. The stream will
* <strong>not</strong> be closed.
* @param saveDocuments if <code>false</code>, documents will not be serialized. Notice that when
* deserializing XML containing clusters but not documents, document references in {@link
* Cluster#getDocuments()} will not be restored.
* @param saveClusters if <code>false</code>, clusters will not be serialized
* @param saveOtherAttributes if <code>false</code>, other attributes will not be serialized
* @throws Exception in case of any problems with serialization
*/
public void serialize(
OutputStream stream, boolean saveDocuments, boolean saveClusters, boolean saveOtherAttributes)
throws Exception {
final Map<String, Object> backupAttributes = attributes;
attributes =
prepareAttributesForSerialization(saveDocuments, saveClusters, saveOtherAttributes);
new Persister().write(this, stream);
attributes = backupAttributes;
}
/** Deserialize from an input stream of characters. */
public static ProcessingResult deserialize(CharSequence input) throws Exception {
return new Persister().read(ProcessingResult.class, input.toString());
}
/**
* Deserializes a {@link ProcessingResult} from an XML stream.
*
* @param input the input XML stream to deserialize a {@link ProcessingResult} from. The stream
* will <strong>not</strong> be closed.
* @return deserialized {@link ProcessingResult}
* @throws Exception is case of any problems with deserialization
*/
public static ProcessingResult deserialize(InputStream input) throws Exception {
return new Persister().read(ProcessingResult.class, input);
}
/**
* Serializes this processing result as JSON to the provided <code>writer</code>. The output
* includes all documents, clusters and other attributes.
*
* <p>This method is not thread-safe, external synchronization must be applied if needed.
*
* @param writer the writer to serialize this processing result to. The writer will
* <strong>not</strong> be closed.
* @throws IOException in case of any problems with serialization
*/
public void serializeJson(Writer writer) throws IOException {
serializeJson(writer, null);
}
/**
* Serializes this processing result as JSON to the provided <code>writer</code>. The output
* includes all documents, clusters and other attributes.
*
* <p>This method is not thread-safe, external synchronization must be applied if needed.
*
* @param writer the writer to serialize this processing result to. The writer will
* <strong>not</strong> be closed.
* @param callback JavaScript function name in which to wrap the JSON response or <code>null
* </code>.
* @throws IOException in case of any problems with serialization
*/
public void serializeJson(Writer writer, String callback) throws IOException {
serializeJson(writer, callback, true, true);
}
/**
* Serializes this processing result as JSON to the provided <code>writer</code>. Documents and
* clusters can be included or skipped in the output as requested. Other attributes are always
* included.
*
* <p>This method is not thread-safe, external synchronization must be applied if needed.
*
* @param writer the writer to serialize this processing result to. The writer will
* <strong>not</strong> be closed.
* @param callback JavaScript function name in which to wrap the JSON response or <code>null
* </code>.
* @param saveDocuments if <code>false</code>, documents will not be serialized.
* @param saveClusters if <code>false</code>, clusters will not be serialized
* @throws IOException in case of any problems with serialization
*/
public void serializeJson(
Writer writer, String callback, boolean saveDocuments, boolean saveClusters)
throws IOException {
serializeJson(writer, callback, false, saveDocuments, saveClusters);
}
/**
* Serializes this processing result as JSON to the provided <code>writer</code>.
*
* <p>This method is not thread-safe, external synchronization must be applied if needed.
*
* @param writer the writer to serialize this processing result to. The writer will
* <strong>not</strong> be closed.
* @param callback JavaScript function name in which to wrap the JSON response or <code>null
* </code>.
* @param indent if <code>true</code>, the output JSON will be pretty-printed
* @param saveDocuments if <code>false</code>, documents will not be serialized.
* @param saveClusters if <code>false</code>, clusters will not be serialized
* @throws IOException in case of any problems with serialization
*/
public void serializeJson(
Writer writer, String callback, boolean indent, boolean saveDocuments, boolean saveClusters)
throws IOException {
serializeJson(writer, callback, indent, saveDocuments, saveClusters, true);
}
/**
* Serializes this processing result as JSON to the provided <code>writer</code>. Documents,
* clusters and other attributes can be included or skipped in the output as requested.
*
* @param writer the writer to serialize this processing result to. The writer will
* <strong>not</strong> be closed.
* @param callback JavaScript function name in which to wrap the JSON response or <code>null
* </code>.
* @param indent if <code>true</code>, the output JSON will be pretty-printed
* @param saveDocuments if <code>false</code>, documents will not be serialized.
* @param saveClusters if <code>false</code>, clusters will not be serialized
* @param saveOtherAttributes if <code>false</code>, other attributes will not be serialized
* @throws IOException in case of any problems with serialization
*/
public void serializeJson(
Writer writer,
String callback,
boolean indent,
boolean saveDocuments,
boolean saveClusters,
boolean saveOtherAttributes)
throws IOException {
final ObjectMapper mapper = new ObjectMapper();
mapper.getFactory().disable(JsonGenerator.Feature.AUTO_CLOSE_TARGET);
mapper.enable(SerializationFeature.INDENT_OUTPUT);
if (StringUtils.isNotBlank(callback)) {
writer.write(callback + "(");
}
final Map<String, Object> attrs =
prepareAttributesForSerialization(saveDocuments, saveClusters, saveOtherAttributes);
mapper.writeValue(writer, attrs);
if (StringUtils.isNotBlank(callback)) {
writer.write(");");
}
}
/**
* Prepares a temporary attributes map for serialization purposes. Includes only the requested
* elements in the map.
*/
private Map<String, Object> prepareAttributesForSerialization(
boolean saveDocuments, boolean saveClusters, boolean saveOtherAttributes) {
final Map<String, Object> tempAttributes = Maps.newHashMap();
if (saveOtherAttributes) {
tempAttributes.putAll(attributes);
tempAttributes.remove(AttributeNames.DOCUMENTS);
tempAttributes.remove(AttributeNames.CLUSTERS);
} else {
tempAttributes.put(AttributeNames.QUERY, attributes.get(AttributeNames.QUERY));
}
if (saveDocuments) {
tempAttributes.put(AttributeNames.DOCUMENTS, getDocuments());
}
if (saveClusters) {
tempAttributes.put(AttributeNames.CLUSTERS, getClusters());
}
return tempAttributes;
}
}