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/*
 * Licensed to the Apache Software Foundation (ASF) under one
 * or more contributor license agreements.  See the NOTICE file
 * distributed with this work for additional information
 * regarding copyright ownership.  The ASF licenses this file
 * to you under the Apache License, Version 2.0 (the
 * "License"); you may not use this file except in compliance
 * with the License.  You may obtain a copy of the License at
 *
 * http://www.apache.org/licenses/LICENSE-2.0
 *
 * Unless required by applicable law or agreed to in writing,
 * software distributed under the License is distributed on an
 * "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY
 * KIND, either express or implied.  See the License for the
 * specific language governing permissions and limitations
 * under the License.
 */
package org.apache.openjpa.meta;

import java.io.Serializable;
import java.security.AccessController;
import java.security.PrivilegedActionException;
import java.util.ArrayList;
import java.util.Arrays;
import java.util.Collection;
import java.util.Collections;
import java.util.HashMap;
import java.util.HashSet;
import java.util.LinkedList;
import java.util.List;
import java.util.Map;
import java.util.Objects;
import java.util.Set;
import java.util.TreeSet;
import java.util.concurrent.ConcurrentHashMap;

import org.apache.openjpa.conf.OpenJPAConfiguration;
import org.apache.openjpa.enhance.DynamicPersistenceCapable;
import org.apache.openjpa.enhance.PCEnhancer;
import org.apache.openjpa.enhance.PCRegistry;
import org.apache.openjpa.enhance.PCRegistry.RegisterClassListener;
import org.apache.openjpa.enhance.PersistenceCapable;
import org.apache.openjpa.event.LifecycleEventManager;
import org.apache.openjpa.lib.conf.Configurable;
import org.apache.openjpa.lib.conf.Configuration;
import org.apache.openjpa.lib.conf.Configurations;
import org.apache.openjpa.lib.log.Log;
import org.apache.openjpa.lib.util.ClassUtil;
import org.apache.openjpa.lib.util.Closeable;
import org.apache.openjpa.lib.util.J2DoPrivHelper;
import org.apache.openjpa.lib.util.Localizer;
import org.apache.openjpa.lib.util.MultiClassLoader;
import org.apache.openjpa.lib.util.Options;
import org.apache.openjpa.lib.util.StringDistance;
import org.apache.openjpa.util.ClassResolver;
import org.apache.openjpa.util.ImplHelper;
import org.apache.openjpa.util.InternalException;
import org.apache.openjpa.util.MetaDataException;
import org.apache.openjpa.util.OpenJPAId;


/**
 * Repository of and factory for persistent metadata.
 *
 * @since 0.3.0
 * @author Abe White
 * @author Steve Kim (query metadata)
 */
public class MetaDataRepository implements PCRegistry.RegisterClassListener, Configurable, Closeable, MetaDataModes,
    Serializable {

    private static final long serialVersionUID = 1L;

    /**
     * Constant to not validate any metadata.
     */
    public static final int VALIDATE_NONE = 0;

    /**
     * Bit flag to validate metadata.
     */
    public static final int VALIDATE_META = 1;

    /**
     * Bit flag to validate mappings.
     */
    public static final int VALIDATE_MAPPING = 2;

    /**
     * Bit flag to validate unenhanced metadata only.
     */
    public static final int VALIDATE_UNENHANCED = 4;

    /**
     * Bit flag for runtime validation. Requires that all classes are enhanced, and performs extra
     * field resolution steps.
     */
    public static final int VALIDATE_RUNTIME = 8;

    protected static final Class[] EMPTY_CLASSES = new Class[0];
    protected static final NonPersistentMetaData[] EMPTY_NON_PERSISTENT = new NonPersistentMetaData[0];
    protected final ClassMetaData[] EMPTY_METAS;
    protected final FieldMetaData[] EMPTY_FIELDS;
    protected final Order[] EMPTY_ORDERS;

    private static final Localizer _loc = Localizer.forPackage(MetaDataRepository.class);

    // system sequence
    private SequenceMetaData _sysSeq = null;
    // cache of parsed metadata, oid class to class, and interface class
    // to metadatas
    private Map, ClassMetaData> _metas = new HashMap<>();
    private Map _metaStringMap = new ConcurrentHashMap<>();
    private Map, Class> _oids = Collections.synchronizedMap(new HashMap<>());
    private Map, Collection>> _impls =
        Collections.synchronizedMap(new HashMap<>());
    private Map, Class> _ifaces = Collections.synchronizedMap(new HashMap<>());
    private Map _queries = new HashMap<>();
    private Map _seqs = new HashMap<>();
    private Map>> _aliases = Collections.synchronizedMap(new HashMap<>());
    private Map, NonPersistentMetaData> _pawares =
        Collections.synchronizedMap(new HashMap<>());
    private Map, NonPersistentMetaData> _nonMapped =
        Collections.synchronizedMap(new HashMap<>());
    private Map, Class> _metamodel = Collections.synchronizedMap(new HashMap<>());

    // map of classes to lists of their subclasses
    private Map, Collection>> _subs =
            Collections.synchronizedMap(new HashMap<>());

    // xml mapping
    protected final XMLMetaData[] EMPTY_XMLMETAS;
    private final Map, XMLMetaData> _xmlmetas = new HashMap<>();

    private transient OpenJPAConfiguration _conf = null;
    private transient Log _log = null;
    private transient InterfaceImplGenerator _implGen = null;
    private transient MetaDataFactory _factory = null;

    private int _resMode = MODE_META | MODE_MAPPING;
    private int _sourceMode = MODE_META | MODE_MAPPING | MODE_QUERY;
    private int _validate = VALIDATE_META | VALIDATE_UNENHANCED;

    // we buffer up any classes that register themselves to prevent
    // reentrancy errors if classes register during a current parse (common)
    private final Collection> _registered = new HashSet<>();

    // set of metadatas we're in the process of resolving
    private final List _resolving = new ArrayList<>();
    private final List _mapping = new ArrayList<>();
    private final List _errs = new LinkedList<>();

    // system listeners
    private LifecycleEventManager.ListenerList _listeners = new LifecycleEventManager.ListenerList(3);
    private boolean _systemListenersActivated = false;

    protected boolean _preload = false;
    protected boolean _preloadComplete = false;
    protected boolean _locking = true;
    private static final String PRELOAD_STR = "Preload";

    // A boolean used to decide whether or not we need to call to PCEnhancer to check whether we have any down level
    // Entities.
    private boolean _logEnhancementLevel = true;

    // A boolean used to decide whether to filter Class objects submitted by the PCRegistry listener system
    private boolean _filterRegisteredClasses = false;

    // we should skip these types for the enhancement
    private Collection> _typesWithoutEnhancement;

    /**
     * Default constructor. Configure via {@link Configurable}.
     */
    public MetaDataRepository() {
        EMPTY_METAS = newClassMetaDataArray(0);
        EMPTY_FIELDS = newFieldMetaDataArray(0);
        EMPTY_ORDERS = newOrderArray(0);
        EMPTY_XMLMETAS = newXMLClassMetaDataArray(0);

    }

    /**
     * Return the configuration for the repository.
     */
    public OpenJPAConfiguration getConfiguration() {
        return _conf;
    }

    /**
     * Return the metadata log.
     */
    public Log getLog() {
        return _log;
    }

    /**
     * The I/O used to load metadata.
     */
    public MetaDataFactory getMetaDataFactory() {
        return _factory;
    }

    /**
     * The I/O used to load metadata.
     */
    public void setMetaDataFactory(MetaDataFactory factory) {
        factory.setRepository(this);
        _factory = factory;
    }

    /**
     * The metadata validation level. Defaults to VALIDATE_META | VALIDATE_UNENHANCED.
     */
    public int getValidate() {
        return _validate;
    }

    /**
     * The metadata validation level. Defaults to VALIDATE_META | VALIDATE_UNENHANCED.
     */
    public void setValidate(int validate) {
        _validate = validate;
    }

    /**
     * The metadata validation level. Defaults to
     * VALIDATE_META | VALIDATE_MAPPING | VALIDATE_UNENHANCED.
     */
    public void setValidate(int validate, boolean on) {
        if (validate == VALIDATE_NONE)
            _validate = validate;
        else if (on)
            _validate |= validate;
        else
            _validate &= ~validate;
    }

    /**
     * The metadata resolution mode. Defaults to MODE_META | MODE_MAPPING.
     */
    public int getResolve() {
        return _resMode;
    }

    /**
     * The metadata resolution mode. Defaults to MODE_META | MODE_MAPPING.
     */
    public void setResolve(int mode) {
        _resMode = mode;
    }

    /**
     * The metadata resolution mode. Defaults to MODE_META | MODE_MAPPING.
     */
    public void setResolve(int mode, boolean on) {
        if (mode == MODE_NONE)
            _resMode = mode;
        else if (on)
            _resMode |= mode;
        else
            _resMode &= ~mode;
    }

    /**
     * The source mode determining what metadata to load. Defaults to
     * MODE_META | MODE_MAPPING | MODE_QUERY.
     */
    public int getSourceMode() {
        return _sourceMode;
    }

    /**
     * The source mode determining what metadata to load. Defaults to
     * MODE_META | MODE_MAPPING | MODE_QUERY.
     */
    public void setSourceMode(int mode) {
        _sourceMode = mode;
    }

    /**
     * The source mode determining what metadata to load. Defaults to
     * MODE_META | MODE_MAPPING | MODE_QUERY.
     */
    public void setSourceMode(int mode, boolean on) {
        if (mode == MODE_NONE)
            _sourceMode = mode;
        else if (on)
            _sourceMode |= mode;
        else
            _sourceMode &= ~mode;
    }

    /**
     * Sets whether this repository will load all known persistent classes at initialization.
     * Defaults to false.
     */
    public boolean getPreload() {
        return _preload;
    }

    /**
     * Sets whether this repository will load all known persistent classes at initialization.
     * Defaults to false.
     */
    public void setPreload(boolean l) {
        _preload = l;
    }


     /**
     * If the openjpa.MetaDataRepository plugin value Preload=true is set, this method will load all
     * MetaData for all persistent classes and will remove locking from this class.
     */
    public synchronized void preload() {
        if (!_preload) {
            return;
        }
        // If pooling EMFs, this method may be invoked more than once. Only perform this work once.
        if (_preloadComplete) {
            return;
        }


        MultiClassLoader multi = AccessController.doPrivileged(J2DoPrivHelper.newMultiClassLoaderAction());
        multi.addClassLoader(AccessController.doPrivileged(J2DoPrivHelper.getContextClassLoaderAction()));
        multi.addClassLoader(AccessController.doPrivileged(J2DoPrivHelper
            .getClassLoaderAction(MetaDataRepository.class)));
        // If a ClassLoader was passed into Persistence.createContainerEntityManagerFactory on the PersistenceUnitInfo
        // we need to add that loader to the chain of classloaders
        ClassResolver resolver = _conf.getClassResolverInstance();
        if (resolver != null) {
            ClassLoader cl = resolver.getClassLoader(null, null);
            if (cl != null) {
                multi.addClassLoader(cl);
            }
        }

        Set classes = getPersistentTypeNames(false, multi);
        if (classes == null || classes.size() == 0) {
            throw new MetaDataException(_loc.get("repos-initializeEager-none"));
        }
        if (_log.isTraceEnabled()) {
            _log.trace(_loc.get("repos-initializeEager-found", classes));
        }

        List> loaded = new ArrayList<>();
        for (String c : classes) {
            try {
                Class cls = AccessController.doPrivileged((J2DoPrivHelper.getForNameAction(c, true, multi)));
                loaded.add(cls);
                // This call may be unnecessary?
                _factory.load(cls, MODE_ALL, multi);
            } catch (PrivilegedActionException pae) {
                throw new MetaDataException(_loc.get("repos-initializeEager-error"), pae);
            }
        }
        resolveAll(multi);

        // Preload XML MetaData
        for (Class cls : loaded) {
            ClassMetaData cmd = getCachedMetaData(cls);
            if (cmd != null) {
                getXMLMetaData(cls);
                for (FieldMetaData fmd : cmd.getFields()) {
                    getXMLMetaData(fmd.getDeclaredType());
                }
            }
        }

        // Hook in this class as a listener and process registered classes list to populate _aliases
        // list.
        PCRegistry.addRegisterClassListener(this);
        processRegisteredClasses(multi);
        _locking = false;
        _preloadComplete = true;
    }


    /**
     * Return the metadata for the given class.
     *
     * @param cls
     *            the class to retrieve metadata for
     * @param envLoader
     *            the environmental class loader, if any
     * @param mustExist
     *            if true, throws a {@link MetaDataException} if no metadata is found
     */
    public ClassMetaData getMetaData(Class cls, ClassLoader envLoader, boolean mustExist) {
        if (_locking) {
            synchronized(this){
                return getMetaDataInternal(cls, envLoader, mustExist);
            }
        } else {
            return getMetaDataInternal(cls, envLoader, mustExist);
        }
    }

    private ClassMetaData getMetaDataInternal(Class cls, ClassLoader envLoader, boolean mustExist) {
        ClassMetaData meta = getMetaDataInternal(cls, envLoader);
        if (meta == null) {
            if (cls != null && DynamicPersistenceCapable.class.isAssignableFrom(cls))
                cls = cls.getSuperclass();

            // if cls is a generated interface, use the user interface
            // to locate metadata
            if (cls != null && _implGen != null && _implGen.isImplType(cls))
                cls = _implGen.toManagedInterface(cls);
            meta = getMetaDataInternal(cls, envLoader);
        }
        if (meta == null && mustExist) {
            if (cls != null && !ImplHelper.isManagedType(_conf, cls))
                throw new MetaDataException(_loc.get("no-meta-notpc", cls)).setFatal(false);

            Set pcNames = getPersistentTypeNames(false, envLoader);
            if (pcNames != null && pcNames.size() > 0)
                throw new MetaDataException(_loc.get("no-meta-types", cls, pcNames));

            throw new MetaDataException(_loc.get("no-meta", cls));
        }
        resolve(meta);
        return meta;
    }

    /**
     * Return the metadata for the given alias name.
     *
     * @param alias
     *            the alias to class to retrieve metadata for
     * @param envLoader
     *            the environmental class loader, if any
     * @param mustExist
     *            if true, throws a {@link MetaDataException} if no metadata is found
     * @see ClassMetaData#getTypeAlias
     */
    public ClassMetaData getMetaData(String alias, ClassLoader envLoader, boolean mustExist) {
        if (alias == null && mustExist)
            throw new MetaDataException(_loc.get("no-alias-meta", alias, _aliases));
        if (alias == null)
            return null;

        // check cache
        processRegisteredClasses(envLoader);
        List> classList = _aliases.get(alias);

        // multiple classes may have been defined with the same alias: we
        // will filter by checking against the current list of the
        // persistent types and filter based on which classes are loadable
        // via the current environment's ClassLoader
        Set pcNames = getPersistentTypeNames(false, envLoader);
        Class cls = null;
        for (int i = 0; classList != null && i < classList.size(); i++) {
            Class c = classList.get(i);
            try {
                // re-load the class in the current environment loader so
                // that we can handle redeployment of the same class name
                Class nc = Class.forName(c.getName(), false, envLoader);

                // if we have specified a list of persistent clases,
                // also check to ensure that the class is in that list
                if (pcNames == null || pcNames.size() == 0 || pcNames.contains(nc.getName())) {
                    cls = nc;
                    if (!classList.contains(cls))
                        classList.add(cls);
                    break;
                }
            } catch (Throwable t) {
                // this happens when the class is not loadable by
                // the environment class loader, so it was probably
                // listed elsewhere; also ignore linkage failures and
                // other class loading problems
            }
        }
        if (cls != null)
            return getMetaData(cls, envLoader, mustExist);

        // maybe this is some type we've seen but just isn't valid
        if (_aliases.containsKey(alias)) {
            if (mustExist)
                throwNoRegisteredAlias(alias);
            return null;
        }

        // We need to synchronize on _aliases because a ConcurrentModificationException can if there
        // is a thread in getAliasNames() AND this class isn't using any locking.
        synchronized (_aliases) {
            // record that this is an invalid type
            _aliases.put(alias, null);
        }

        if (!mustExist)
            return null;
        return throwNoRegisteredAlias(alias);
    }

    private ClassMetaData throwNoRegisteredAlias(String alias) {
        String close = getClosestAliasName(alias);
        if (close != null)
            throw new MetaDataException(_loc.get("no-alias-meta-hint", alias, _aliases, close));
        else
            throw new MetaDataException(_loc.get("no-alias-meta", alias, _aliases));
    }

    /**
     * @return the nearest match to the specified alias name
     * @since 1.1.0
     */
    public String getClosestAliasName(String alias) {
        Collection aliases = getAliasNames();
        return StringDistance.getClosestLevenshteinDistance(alias, aliases);
    }

    /**
     * @return the registered alias names
     * @since 1.1.0
     */
    public Collection getAliasNames() {
        if (_locking) {
            synchronized (_aliases) {
                return getAliasNamesInternal();
            }
        } else {
            return getAliasNamesInternal();
        }
    }

    private Collection getAliasNamesInternal() {
        Collection aliases = new HashSet<>();
        for(Map.Entry>> e : _aliases.entrySet()){
            if (e.getValue() != null) {
                aliases.add(e.getKey());
            }
        }
        return aliases;
    }

    /**
     * Internal method to get the metadata for the given class, without resolving it.
     */
    private ClassMetaData getMetaDataInternal(Class cls, ClassLoader envLoader) {
        if (cls == null)
            return null;

        // check cache for existing metadata, or give up if no metadata and
        // our list of configured persistent types doesn't include the class
        ClassMetaData meta = _metas.get(cls);
        if (meta != null && ((meta.getSourceMode() & MODE_META) != 0 || (_sourceMode & MODE_META) == 0))
            return meta;

        // if runtime, cut off search if not in pc list. we don't do this at
        // dev time so that user can manipulate persistent classes he's writing
        // before adding them to the list
        if ((_validate & VALIDATE_RUNTIME) != 0) {
            Set pcNames = getPersistentTypeNames(false, envLoader);
            if (pcNames != null && !pcNames.contains(cls.getName()))
                return meta;
        }

        if (meta == null) {
            // check to see if maybe we know this class has no metadata
            if (_metas.containsKey(cls))
                return null;

            // make sure this isn't an obviously bad class
            if (cls.isPrimitive() || cls.getName().startsWith("java.") || cls == PersistenceCapable.class)
                return null;

            // designed to get around jikes 1.17 / JDK1.5 issue where static
            // initializers are not invoked when a class is referenced, so the
            // class never registers itself with the system
            if ((_validate & VALIDATE_RUNTIME) != 0) {
                try {
                    Class.forName(cls.getName(), true, AccessController.doPrivileged(J2DoPrivHelper
                        .getClassLoaderAction(cls)));
                } catch (Throwable t) {
                }
            }
        }

        // not in cache: load metadata or mappings depending on source mode.
        // loading metadata might also load mappings, but doesn't have to
        int mode = 0;
        if ((_sourceMode & MODE_META) != 0)
            mode = _sourceMode & ~MODE_MAPPING;
        else if ((_sourceMode & MODE_MAPPING) == 0)
            mode = _sourceMode;
        if (mode != MODE_NONE) {
            if (_log.isTraceEnabled())
                _log.trace(_loc.get("load-cls", cls, toModeString(mode)));
            _factory.load(cls, mode, envLoader);
        }

        // check cache again
        if (meta == null)
            meta = _metas.get(cls);
        if (meta != null && ((meta.getSourceMode() & MODE_META) != 0 || (_sourceMode & MODE_META) == 0))
            return meta;

        // record that this class has no metadata; checking for this later
        // speeds things up in environments with slow class loading
        // like appservers
        if (meta != null)
            removeMetaData(meta);
        _metas.put(cls, null);
        return null;
    }

    /**
     * Return a string representation of the given mode flags.
     */
    private static String toModeString(int mode) {
        StringBuilder buf = new StringBuilder(31);
        if ((mode & MODE_META) != 0)
            buf.append("[META]");
        if ((mode & MODE_QUERY) != 0)
            buf.append("[QUERY]");
        if ((mode & MODE_MAPPING) != 0)
            buf.append("[MAPPING]");
        if ((mode & MODE_MAPPING_INIT) != 0)
            buf.append("[MAPPING_INIT]");
        return buf.toString();
    }

    /**
     * Prepare metadata for mapping resolution. This method might map parts of the metadata that
     * don't rely on other classes being mapped, but that other classes might rely on during their
     * own mapping (for example, primary key fields). By default, this method only calls
     * {@link ClassMetaData#defineSuperclassFields}.
     */
    protected void prepareMapping(ClassMetaData meta) {
        meta.defineSuperclassFields(false);
    }

    /**
     * Resolve the given metadata if needed. There are three goals:
     * 
    *
  1. Make sure no unresolved metadata gets back to the client.
  2. *
  3. Avoid infinite reentrant calls for mutually-dependent metadatas by allowing unresolved * metadata to be returned to other metadatas.
  4. *
  5. Always make sure the superclass metadata is resolved before the subclass metadata so that * the subclass can access the super's list of fields.
  6. *
* Note that the code calling this method is synchronized, so this method doesn't have to be. */ private void resolve(ClassMetaData meta) { // return anything that has its metadata resolved, because that means // it is either fully resolved or must at least be in the process of // resolving mapping, etc since we do that right after meta resolve if (meta == null || _resMode == MODE_NONE || (meta.getResolve() & MODE_META) != 0) return; // resolve metadata List resolved = resolveMeta(meta); if (resolved == null) return; // load mapping data for (ClassMetaData data : resolved) { loadMapping(data); } for (ClassMetaData metaData : resolved) { preMapping(metaData); } // resolve mappings boolean err = true; if ((_resMode & MODE_MAPPING) != 0) for (ClassMetaData classMetaData : resolved) { err &= resolveMapping(classMetaData); } // throw errors encountered // OPENJPA-1535 Always throw a MetaDataException because callers // of loadRegisteredClassMetaData expect only MetaDataException // to be thrown. if (err && !_errs.isEmpty()) { RuntimeException re; if ((_errs.size() == 1) && (_errs.get(0) instanceof MetaDataException)) { re = _errs.get(0); } else { re = new MetaDataException(_loc.get("resolve-errs")) .setNestedThrowables(_errs .toArray(new Exception[_errs.size()])); } _errs.clear(); throw re; } } /** * Resolve metadata mode, returning list of processed metadadatas, or null if we're still in the * process of resolving other metadatas. */ private List resolveMeta(ClassMetaData meta) { if (meta.getPCSuperclass() == null) { // set superclass Class sup = meta.getDescribedType().getSuperclass(); ClassMetaData supMeta; while (sup != null && sup != Object.class) { supMeta = getMetaData(sup, meta.getEnvClassLoader(), false); if (supMeta != null) { meta.setPCSuperclass(sup); meta.setPCSuperclassMetaData(supMeta); break; } else sup = sup.getSuperclass(); } if (meta.getDescribedType().isInterface()) { Class[] sups = meta.getDescribedType().getInterfaces(); for (Class aClass : sups) { supMeta = getMetaData(aClass, meta.getEnvClassLoader(), false); if (supMeta != null) { meta.setPCSuperclass(sup); meta.setPCSuperclassMetaData(supMeta); break; } } } if (_log.isTraceEnabled()) _log.trace(_loc.get("assigned-sup", meta, meta.getPCSuperclass())); } // resolve relation primary key fields for mapping dependencies FieldMetaData[] fmds = meta.getDeclaredFields(); for (FieldMetaData fmd : fmds) if (fmd.isPrimaryKey()) getMetaData(fmd.getDeclaredType(), meta.getEnvClassLoader(), false); // resolve metadata; if we're not in the process of resolving // others, this will return the set of interrelated metas that // resolved return processBuffer(meta, _resolving, MODE_META); } /** * Load mapping information for the given metadata. */ private void loadMapping(ClassMetaData meta) { if ((meta.getResolve() & MODE_MAPPING) != 0) return; // load mapping information if ((meta.getSourceMode() & MODE_MAPPING) == 0 && (_sourceMode & MODE_MAPPING) != 0) { // embedded-only metadata doesn't have mapping, so always loaded if (meta.isEmbeddedOnly()) meta.setSourceMode(MODE_MAPPING, true); else { // load mapping data int mode = _sourceMode & ~MODE_META; if (_log.isTraceEnabled()) _log.trace(_loc.get("load-mapping", meta, toModeString(mode))); try { _factory.load(meta.getDescribedType(), mode, meta.getEnvClassLoader()); } catch (RuntimeException re) { removeMetaData(meta); _errs.add(re); } } } } /** * Pre-mapping preparation. */ private void preMapping(ClassMetaData meta) { if ((meta.getResolve() & MODE_MAPPING) != 0) return; // prepare mappings for resolve; if not resolving mappings, then // make sure any superclass fields defined in metadata are resolved try { if ((_resMode & MODE_MAPPING) != 0) { if (_log.isTraceEnabled()) _log.trace(_loc.get("prep-mapping", meta)); prepareMapping(meta); } else meta.defineSuperclassFields(false); } catch (RuntimeException re) { removeMetaData(meta); _errs.add(re); } } /** * Resolve and initialize mapping. * * @return false if we're still in the process of resolving mappings */ private boolean resolveMapping(ClassMetaData meta) { List mapped = processBuffer(meta, _mapping, MODE_MAPPING); if (mapped == null) return false; // initialize mapping for runtime use if ((_resMode & MODE_MAPPING_INIT) != 0) { for (ClassMetaData classMetaData : mapped) { meta = classMetaData; try { meta.resolve(MODE_MAPPING_INIT); } catch (RuntimeException re) { removeMetaData(meta); _errs.add(re); } } } return true; } /** * Process the given metadata and the associated buffer. */ private List processBuffer(ClassMetaData meta, List buffer, int mode) { // add the metadata to the buffer unless an instance for the same entity // is already there for (ClassMetaData cmd : buffer) if (cmd.getDescribedType().equals(meta.getDescribedType())) return null; // if we're already processing a metadata, just buffer this one; when // the initial metadata finishes processing, we traverse the buffer // and process all the others that were introduced during reentrant // calls buffer.add(meta); if (buffer.size() != 1) return null; // continually pop a metadata and process it until we run out; note // that each processing call might place more metas in the buffer as // one class tries to access metadata for another ClassMetaData buffered; List processed = new ArrayList<>(5); while (!buffer.isEmpty()) { buffered = buffer.get(0); try { buffered.resolve(mode); processed.add(buffered); buffer.remove(buffered); } catch (RuntimeException re) { _errs.add(re); // any exception during resolution of one type means we can't // resolve any of the related types, so clear buffer. this also // ensures that if two types relate to each other and one // dies, we don't get into infinite cycles for (ClassMetaData cmd : buffer) { removeMetaData(cmd); if (cmd != buffered) { _errs.add(new MetaDataException(_loc.get("prev-errs", cmd, buffered))); } } buffer.clear(); } } return processed; } /** * Return all the metadata instances currently in the repository. */ public ClassMetaData[] getMetaDatas() { if (_locking) { synchronized(this){ return getMetaDatasInternal(); } } else { return getMetaDatasInternal(); } } private ClassMetaData[] getMetaDatasInternal() { // prevent concurrent mod errors when resolving one metadata // introduces others ClassMetaData[] metas = _metas.values().toArray(new ClassMetaData[_metas.size()]); for (ClassMetaData classMetaData : metas) if (classMetaData != null) getMetaData(classMetaData.getDescribedType(), classMetaData.getEnvClassLoader(), true); List resolved = new ArrayList<>(_metas.size()); for (ClassMetaData meta : _metas.values()) { if (meta != null) resolved.add(meta); } metas = resolved.toArray(newClassMetaDataArray(resolved.size())); Arrays.sort(metas); return metas; } /** * Return the cached metadata for the given class, without any resolution. Return null if none. */ public ClassMetaData getCachedMetaData(Class cls) { return _metas.get(cls); } /** * Create a new metadata, populate it with default information, add it to the repository, and * return it. Use the default access type. */ public ClassMetaData addMetaData(Class cls) { return addMetaData(cls, AccessCode.UNKNOWN); } /** * Create a new metadata, populate it with default information, add it to the repository, and * return it. * * @param access * the access type to use in populating metadata */ public ClassMetaData addMetaData(Class cls, int access) { return addMetaData(cls, access, false); } /** * Create a new metadata, populate it with default information, add it to the repository, and * return it. * * @param access * the access type to use in populating metadata */ public ClassMetaData addMetaData(Class cls, int access, boolean ignoreTransient) { if (cls == null || cls.isPrimitive()) return null; ClassMetaData meta = newClassMetaData(cls); _factory.getDefaults().populate(meta, access, ignoreTransient); // synchronize on this rather than the map, because all other methods // that access _metas are synchronized on this if (_locking) { synchronized(this){ return metasPutInternal(cls, meta); } } else { return metasPutInternal(cls, meta); } } private ClassMetaData metasPutInternal(Class cls, ClassMetaData meta){ if (_pawares.containsKey(cls)) throw new MetaDataException(_loc.get("pc-and-aware", cls)); _metas.put(cls, meta); return meta; } /** * Create a new class metadata instance. */ protected ClassMetaData newClassMetaData(Class type) { return new ClassMetaData(type, this); } /** * Create a new array of the proper class metadata subclass. */ protected ClassMetaData[] newClassMetaDataArray(int length) { return new ClassMetaData[length]; } /** * Create a new field metadata instance. */ protected FieldMetaData newFieldMetaData(String name, Class type, ClassMetaData owner) { return new FieldMetaData(name, type, owner); } /** * Create a new array of the proper field metadata subclass. */ protected FieldMetaData[] newFieldMetaDataArray(int length) { return new FieldMetaData[length]; } /** * Create a new array of the proper xml class metadata subclass. */ protected XMLMetaData[] newXMLClassMetaDataArray(int length) { return new XMLClassMetaData[length]; } /** * Create a new embedded class metadata instance. */ protected ClassMetaData newEmbeddedClassMetaData(ValueMetaData owner) { return new ClassMetaData(owner); } /** * Create a new value metadata instance. */ protected ValueMetaData newValueMetaData(FieldMetaData owner) { return new ValueMetaDataImpl(owner); } /** * Create an {@link Order} for the given field and declaration. This method delegates to * {@link #newRelatedFieldOrder} and {@link #newValueOrder(FieldMetaData, boolean)} by default. */ protected Order newOrder(FieldMetaData owner, String name, boolean asc) { // paths can start with (or equal) '#element' if (name.startsWith(Order.ELEMENT)) name = name.substring(Order.ELEMENT.length()); if (name.length() == 0) return newValueOrder(owner, asc); // next token should be '.' if (name.charAt(0) == '.') name = name.substring(1); // related field ClassMetaData meta = owner.getElement().getTypeMetaData(); if (meta == null) throw new MetaDataException(_loc.get("nonpc-field-orderable", owner, name)); FieldMetaData rel = getOrderByField(meta, name); if (rel == null) throw new MetaDataException(_loc.get("bad-field-orderable", owner, name)); return newRelatedFieldOrder(owner, rel, asc); } public FieldMetaData getOrderByField(ClassMetaData meta, String orderBy) { FieldMetaData field = meta.getField(orderBy); if (field != null) return field; int dotIdx = orderBy.indexOf("."); if (dotIdx == -1) return null; String fieldName = orderBy.substring(0, dotIdx); FieldMetaData field1 = meta.getField(fieldName); if (field1 == null) return null; ClassMetaData meta1 = field1.getEmbeddedMetaData(); if (meta1 == null) return null; String mappedBy1 = orderBy.substring(dotIdx + 1); return getOrderByField(meta1, mappedBy1); } /** * Order by the field value. */ protected Order newValueOrder(FieldMetaData owner, boolean asc) { return new InMemoryValueOrder(asc, getConfiguration()); } /** * Order by a field of the related type. */ protected Order newRelatedFieldOrder(FieldMetaData owner, FieldMetaData rel, boolean asc) { return new InMemoryRelatedFieldOrder(rel, asc, getConfiguration()); } /** * Create an array of orders of the given size. */ protected Order[] newOrderArray(int size) { return new Order[size]; } /** * Remove a metadata instance from the repository. * * @return true if removed, false if not in this repository */ public boolean removeMetaData(ClassMetaData meta) { if (meta == null) return false; return removeMetaData(meta.getDescribedType()); } /** * Remove a metadata instance from the repository. * * @return true if removed, false if not in this repository */ public boolean removeMetaData(Class cls) { if(_locking){ synchronized(this){ return removeMetaDataInternal(cls); } }else{ return removeMetaDataInternal(cls); } } private boolean removeMetaDataInternal(Class cls) { if (cls == null) return false; if (_metas.remove(cls) != null) { Class impl = _ifaces.remove(cls); if (impl != null) _metas.remove(impl); return true; } return false; } /** * Add the given metadata as declared interface implementation. */ void addDeclaredInterfaceImpl(ClassMetaData meta, Class iface) { if (_locking) { synchronized (_impls) { addDeclaredInterfaceImplInternal(meta, iface); } } else { addDeclaredInterfaceImplInternal(meta, iface); } } private void addDeclaredInterfaceImplInternal(ClassMetaData meta, Class iface) { Collection> vals = _impls.get(iface); // check to see if the superclass already declares to avoid dups if (vals != null) { ClassMetaData sup = meta.getPCSuperclassMetaData(); for (; sup != null; sup = sup.getPCSuperclassMetaData()) if (vals.contains(sup.getDescribedType())) return; } addToCollection(_impls, iface, meta.getDescribedType(), false); } /** * Set the implementation for the given managed interface. */ void setInterfaceImpl(ClassMetaData meta, Class impl) { if (_locking) { synchronized (this) { setInterfaceImplInternal(meta, impl); } } else { setInterfaceImplInternal(meta, impl); } } private void setInterfaceImplInternal(ClassMetaData meta, Class impl) { if (!meta.isManagedInterface()) throw new MetaDataException(_loc.get("not-managed-interface", meta, impl)); _ifaces.put(meta.getDescribedType(), impl); addDeclaredInterfaceImpl(meta, meta.getDescribedType()); ClassMetaData sup = meta.getPCSuperclassMetaData(); while (sup != null) { // record superclass interface info while we can as well as we // will only register concrete superclass in PCRegistry sup.clearSubclassCache(); addToCollection(_subs, sup.getDescribedType(), impl, true); sup = sup.getPCSuperclassMetaData(); } } InterfaceImplGenerator getImplGenerator() { return _implGen; } /** * Return the least-derived class metadata for the given application identity object. * * @param oid * the oid to get the metadata for * @param envLoader * the environmental class loader, if any * @param mustExist * if true, throws a {@link MetaDataException} if no metadata is found */ public ClassMetaData getMetaData(Object oid, ClassLoader envLoader, boolean mustExist) { if (oid == null && mustExist) throw new MetaDataException(_loc.get("no-oid-meta", oid, "?", _oids.toString())); if (oid == null) return null; if (oid instanceof OpenJPAId) { Class cls = ((OpenJPAId) oid).getType(); return getMetaData(cls, envLoader, mustExist); } // check cache processRegisteredClasses(envLoader); Class cls = _oids.get(oid.getClass()); if (cls != null) return getMetaData(cls, envLoader, mustExist); // maybe this is some type we've seen but just isn't valid if (_oids.containsKey(oid.getClass())) { if (mustExist) throw new MetaDataException(_loc.get("no-oid-meta", oid, oid.getClass(), _oids)); return null; } // if still not match, register any classes that look similar to the // oid class and check again resolveIdentityClass(oid); if (processRegisteredClasses(envLoader).length > 0) { cls = _oids.get(oid.getClass()); if (cls != null) return getMetaData(cls, envLoader, mustExist); } // record that this is an invalid type _oids.put(oid.getClass(), null); if (!mustExist) return null; throw new MetaDataException(_loc.get("no-oid-meta", oid, oid.getClass(), _oids)).setFailedObject(oid); } /** * Make some guesses about the name of a target class for an unknown application identity class. */ private void resolveIdentityClass(Object oid) { if (oid == null) return; Class oidClass = oid.getClass(); if (_log.isTraceEnabled()) _log.trace(_loc.get("resolve-identity", oidClass)); ClassLoader cl = AccessController.doPrivileged(J2DoPrivHelper.getClassLoaderAction(oidClass)); String className; while (oidClass != null && oidClass != Object.class) { className = oidClass.getName(); // we take a brute-force approach: try to load all the class' // substrings. this will handle the following common naming cases: // // com.company.MyClass$ID -> com.company.MyClass // com.company.MyClassId -> com.company.MyClass // com.company.MyClassOid -> com.company.MyClass // com.company.MyClassPK -> com.company.MyClass // // this isn't the fastest thing possible, but this method will // only be called once per JVM per unknown app id class for (int i = className.length(); i > 1; i--) { if (className.charAt(i - 1) == '.') break; try { Class.forName(className.substring(0, i), true, cl); } catch (Exception e) { } // consume all exceptions } // move up the OID hierarchy oidClass = oidClass.getSuperclass(); } } /** * Return all least-derived metadatas with some mapped assignable type that implement the given * class. * * @param cls * the class or interface to retrieve implementors for * @param envLoader * the environmental class loader, if any * @param mustExist * if true, throws a {@link MetaDataException} if no metadata is found */ public ClassMetaData[] getImplementorMetaDatas(Class cls, ClassLoader envLoader, boolean mustExist) { if (cls == null && mustExist) throw new MetaDataException(_loc.get("no-meta", cls)); if (cls == null) return EMPTY_METAS; // get impls of given interface / abstract class loadRegisteredClassMetaData(envLoader); Collection> vals = _impls.get(cls); ClassMetaData[] mapped = null; if (vals != null) { if (_locking) { synchronized (vals) { mapped = getImplementorMetaDatasInternal(vals, envLoader, mustExist); } } else { mapped = getImplementorMetaDatasInternal(vals, envLoader, mustExist); } } if (mapped == null && mustExist) throw new MetaDataException(_loc.get("no-meta", cls)); if (mapped == null) return EMPTY_METAS; return mapped; } private ClassMetaData[] getImplementorMetaDatasInternal(Collection> classes, ClassLoader envLoader, boolean mustExist) { Collection mapped = new ArrayList<>(classes.size()); ClassMetaData meta = null; for (Class c : classes) { meta = getMetaData(c, envLoader, true); if (meta.isMapped() || meta.getMappedPCSubclassMetaDatas().length > 0) { mapped.add(meta); } } return mapped.toArray(new ClassMetaData[mapped.size()]); } /** * Gets the metadata corresponding to the given persistence-aware class. Returns null, if the * given class is not registered as persistence-aware. */ public NonPersistentMetaData getPersistenceAware(Class cls) { return _pawares.get(cls); } public boolean skipMetadata(final Class cls) { if (cls == null || cls.isEnum()) { return true; } if (_typesWithoutEnhancement == null) { return false; } return _typesWithoutEnhancement.stream().anyMatch(it -> it.isAssignableFrom(cls)); } /** * Gets all the metadatas for persistence-aware classes * * @return empty array if no class has been registered as pers-aware */ public NonPersistentMetaData[] getPersistenceAwares() { if (_locking) { synchronized (_pawares) { return getPersistenceAwaresInternal(); } } else { return getPersistenceAwaresInternal(); } } private NonPersistentMetaData[] getPersistenceAwaresInternal() { if (_pawares.isEmpty()) return EMPTY_NON_PERSISTENT; return _pawares.values().toArray(new NonPersistentMetaData[_pawares.size()]); } /** * Add the given class as persistence-aware. * * @param cls * non-null and must not alreaddy be added as persitence-capable */ public NonPersistentMetaData addPersistenceAware(Class cls) { if (cls == null) return null; if (_locking) { synchronized (this) { return addPersistenceAwareInternal(cls); } } else { return addPersistenceAwareInternal(cls); } } private NonPersistentMetaData addPersistenceAwareInternal(Class cls) { if (_pawares.containsKey(cls)) return _pawares.get(cls); if (getCachedMetaData(cls) != null) throw new MetaDataException(_loc.get("pc-and-aware", cls)); NonPersistentMetaData meta = new NonPersistentMetaData(cls, this, NonPersistentMetaData.TYPE_PERSISTENCE_AWARE); _pawares.put(cls, meta); return meta; } /** * Remove a persitence-aware class from the repository * * @return true if removed */ public boolean removePersistenceAware(Class cls) { return _pawares.remove(cls) != null; } /** * Gets the metadata corresponding to the given non-mapped interface. Returns null, if the given * interface is not registered as persistence-aware. */ public NonPersistentMetaData getNonMappedInterface(Class iface) { return _nonMapped.get(iface); } /** * Gets the corresponding metadatas for all registered, non-mapped interfaces * * @return empty array if no non-mapped interface has been registered. */ public NonPersistentMetaData[] getNonMappedInterfaces() { if (_locking) { synchronized (_nonMapped) { return getNonMappedInterfacesInternal(); } } else { return getNonMappedInterfacesInternal(); } } private NonPersistentMetaData[] getNonMappedInterfacesInternal() { if (_nonMapped.isEmpty()) return EMPTY_NON_PERSISTENT; return _nonMapped.values().toArray(new NonPersistentMetaData[_nonMapped.size()]); } /** * Add the given non-mapped interface to the repository. * * @param iface * the non-mapped interface */ public NonPersistentMetaData addNonMappedInterface(Class iface) { if (iface == null) return null; if (!iface.isInterface()) throw new MetaDataException(_loc.get("not-non-mapped", iface)); if (_locking) { synchronized (this) { return addNonMappedInterfaceInternal(iface); } } else { return addNonMappedInterfaceInternal(iface); } } private NonPersistentMetaData addNonMappedInterfaceInternal(Class iface) { if (_nonMapped.containsKey(iface)) return _nonMapped.get(iface); if (getCachedMetaData(iface) != null) throw new MetaDataException(_loc.get("non-mapped-pc", iface)); NonPersistentMetaData meta = new NonPersistentMetaData(iface, this, NonPersistentMetaData.TYPE_NON_MAPPED_INTERFACE); _nonMapped.put(iface, meta); return meta; } /** * Remove a non-mapped interface from the repository * * @return true if removed */ public boolean removeNonMappedInterface(Class iface) { return _nonMapped.remove(iface) != null; } /** * Clear the cache of parsed metadata. This method also clears the internal * {@link MetaDataFactory MetaDataFactory}'s cache. */ public void clear() { if (_log.isTraceEnabled()) _log.trace(_loc.get("clear-repos", this)); if (_locking) { synchronized (this) { clearInternal(); } } else { clearInternal(); } } private void clearInternal(){ // Recreating these datastructures is probably faster than calling clear. Future change? _metas.clear(); _oids.clear(); _subs.clear(); _impls.clear(); _queries.clear(); _seqs.clear(); _registered.clear(); _factory.clear(); _aliases.clear(); _pawares.clear(); _nonMapped.clear(); _metaStringMap.clear(); } /** * Return the set of configured persistent classes, or null if the user did not configure any. * * @param devpath * if true, search for metadata files in directories in the classpath if no classes * are configured explicitly * @param envLoader * the class loader to use, or null for default */ public Set getPersistentTypeNames(boolean devpath, ClassLoader envLoader) { if (_locking) { synchronized (this) { return getPersistentTypeNamesInternal(devpath, envLoader); } } else { return getPersistentTypeNamesInternal(devpath, envLoader); } } private Set getPersistentTypeNamesInternal(boolean devpath, ClassLoader envLoader) { return _factory.getPersistentTypeNames(devpath, envLoader); } /** * Load the persistent classes named in configuration. * This ensures that all subclasses and application identity classes of * each type are known in advance, without having to rely on the * application loading the classes before performing operations that * might involve them. * * @param devpath if true, search for metadata files in directories * in the classpath if the no classes are configured explicitly * @param envLoader the class loader to use, or null for default * @return the loaded classes, or empty collection if none */ public Collection> loadPersistentTypes(boolean devpath, ClassLoader envLoader) { return loadPersistentTypes(devpath, envLoader, false); } /** * Load the persistent classes named in configuration. This ensures that all subclasses and * application identity classes of each type are known in advance, without having to rely on the * application loading the classes before performing operations that might involve them. * * @param devpath * if true, search for metadata files in directories in the classpath if the no * classes are configured explicitly * @param envLoader * the class loader to use, or null for default * @param mustExist * if true then empty list of classes or any unloadable but specified class will * raise an exception. * @return the loaded classes, or empty collection if none */ public Collection> loadPersistentTypes(boolean devpath, ClassLoader envLoader, boolean mustExist) { if (_locking) { synchronized (this) { return loadPersistentTypesInternal(devpath, envLoader, mustExist); } } else { return loadPersistentTypesInternal(devpath, envLoader, mustExist); } } private Collection> loadPersistentTypesInternal(boolean devpath, ClassLoader envLoader, boolean mustExist) { Set names = getPersistentTypeNames(devpath, envLoader); if (names == null || names.isEmpty()) { if (!mustExist) return Collections.emptyList(); else throw new MetaDataException(_loc.get("eager-no-class-found")); } // attempt to load classes so that they get processed ClassLoader clsLoader = _conf.getClassResolverInstance().getClassLoader(getClass(), envLoader); List> classes = new ArrayList<>(names.size()); Class cls; for (String className : names) { cls = classForName(className, clsLoader); if (_factory.isMetaClass(cls)) { setMetaModel(cls); continue; } if (skipMetadata(cls)) { continue; } if (cls != null) { classes.add(cls); // if the class is an interface, load its metadata to kick // off the impl generator if (cls.isInterface()) getMetaData(cls, clsLoader, false); } else if (cls == null && mustExist) { throw new MetaDataException(_loc.get("eager-class-not-found", className)); } } return classes; } /** * Return the class for the given name, or null if not loadable. */ private Class classForName(String name, ClassLoader loader) { try { return Class.forName(name, true, loader); } catch (Exception e) { if ((_validate & VALIDATE_RUNTIME) != 0) { if (_log.isWarnEnabled()) _log.warn(_loc.get("bad-discover-class", name, loader)); } else if (_log.isInfoEnabled()) _log.info(_loc.get("bad-discover-class", name, loader)); if (_log.isTraceEnabled()) _log.trace(e); } catch (NoSuchMethodError nsme) { if (nsme.getMessage().indexOf(".pc") == -1) throw nsme; // if the error is about a method that uses the PersistenceCapable // 'pc' method prefix, perform some logging and continue. This // probably just means that the class is not yet enhanced. if ((_validate & VALIDATE_RUNTIME) != 0) { if (_log.isWarnEnabled()) _log.warn(_loc.get("bad-discover-class", name, loader)); } else if (_log.isInfoEnabled()) _log.info(_loc.get("bad-discover-class", name, loader)); if (_log.isTraceEnabled()) _log.trace(nsme); } catch (NoClassDefFoundError ndcfe) { throw ndcfe; } return null; } /** * Return all known subclasses for the given class mapping. Note that this method only works * during runtime when the repository is registered as a {@link RegisterClassListener}. */ Collection> getPCSubclasses(Class cls) { Collection> subs = _subs.get(cls); if (subs == null) return Collections.emptyList(); return subs; } // ////////////////////////////////////// // RegisterClassListener implementation // ////////////////////////////////////// @Override public void register(Class cls) { // buffer registered classes until an oid metadata request is made, // at which point we'll parse everything in the buffer synchronized (_registered) { _registered.add(cls); registerAlias(cls); } } /** * Parses the metadata for all registered classes. */ private void loadRegisteredClassMetaData(ClassLoader envLoader) { Class[] reg = processRegisteredClasses(envLoader); for (Class aClass : reg) { try { getMetaData(aClass, envLoader, false); } catch (MetaDataException me) { if (_log.isWarnEnabled()) _log.warn(me); } } } /** * Updates our data structures with the latest registered classes. * * This method is synchronized to make sure that all data structures are fully updated * before other threads attempt to call this method */ synchronized Class[] processRegisteredClasses(ClassLoader envLoader) { Class[] reg; /*Synchronize `_registered` cache to block MetaDataRepository.register() from adding * to the cache while we copy, causing a ConcurrentModificationException */ synchronized (_registered) { if (_registered.isEmpty()) { return EMPTY_CLASSES; } // copy into new collection to avoid concurrent mod errors on reentrant // registrations reg = _registered.toArray(new Class[_registered.size()]); _registered.clear(); } Collection pcNames = getPersistentTypeNames(false, envLoader); Collection> failed = null; for (Class aClass : reg) { // Don't process types that aren't listed by the user; it may belong to a different persistence unit. if (pcNames != null && !pcNames.isEmpty() && !pcNames.contains(aClass.getName())) { continue; } // If the compatibility option "filterPCRegistryClasses" is enabled, then verify that the type is // accessible to the envLoader/Thread Context ClassLoader if (_filterRegisteredClasses) { Log log = (_conf == null) ? null : _conf.getLog(OpenJPAConfiguration.LOG_RUNTIME); ClassLoader loadCL = (envLoader != null) ? envLoader : AccessController.doPrivileged(J2DoPrivHelper.getContextClassLoaderAction()); try { Class classFromAppClassLoader = Class.forName(aClass.getName(), true, loadCL); if (!aClass.equals(classFromAppClassLoader)) { // This is a class that belongs to a ClassLoader not associated with the Application, // so it should be processed. if (log != null && log.isTraceEnabled()) { log.trace( "Metadata Repository will ignore Class " + aClass.getName() + ", since it originated from a ClassLoader not associated with the application."); } continue; } } catch (ClassNotFoundException cnfe) { // Catch exception and log its occurrence, and permit MDR processing to continue to preserve // original behavior. if (log != null && log.isTraceEnabled()) { log.trace("The Class " + aClass.getName() + " was identified as a persistent class " + "by configuration, but the Class could not be found."); } } } checkEnhancementLevel(aClass); try { processRegisteredClass(aClass); } catch (Throwable t) { if (!_conf.getRetryClassRegistration()) throw new MetaDataException(_loc.get("error-registered", aClass), t); if (_log.isWarnEnabled()) _log.warn(_loc.get("failed-registered", aClass), t); if (failed == null) failed = new ArrayList<>(); failed.add(aClass); } } if (failed != null) { if (_locking) { synchronized (_registered) { _registered.addAll(failed); } } else { _registered.addAll(failed); } } return reg; } /** * Updates our datastructures with the given registered class. Relies on the fact that a child * class cannot register itself without also registering its parent class by specifying its * persistence capable superclass in the registration event. */ private void processRegisteredClass(Class cls) { if (_log.isTraceEnabled()) _log.trace(_loc.get("process-registered", cls)); // update subclass lists; synchronize on this because accessing _metas // requires it Class leastDerived = cls; synchronized (this) { ClassMetaData meta; for (Class anc = cls; (anc = PCRegistry.getPersistentSuperclass(anc)) != null;) { addToCollection(_subs, anc, cls, true); meta = _metas.get(anc); if (meta != null) meta.clearSubclassCache(); leastDerived = anc; } } // update oid mappings if this is a base concrete class Object oid = null; try { oid = PCRegistry.newObjectId(cls); } catch (InternalException ie) { // thrown for single field identity with null pk field value } if (oid != null) { Class existing = _oids.get(oid.getClass()); if (existing != null) { // if there is already a class for this OID, then we know // that multiple classes are using the same OID: therefore, // put the least derived PC superclass into the map. This // gets around the problem of an abstract PC superclass // using application identity (since newObjectId // will return null for abstract classes). Class sup = cls; while (PCRegistry.getPersistentSuperclass(sup) != null) sup = PCRegistry.getPersistentSuperclass(sup); _oids.put(oid.getClass(), sup); } else if (existing == null || cls.isAssignableFrom(existing)) _oids.put(oid.getClass(), cls); } // update mappings from interfaces and non-pc superclasses to // pc implementing types if (_locking) { synchronized (_impls) { updateImpls(cls, leastDerived, cls); } } else { updateImpls(cls, leastDerived, cls); } // set alias for class registerAlias(cls); } /** * Register the given class to the list of known aliases. * The alias is registered only if the class has been enhanced. * */ void registerAlias(Class cls) { registerAlias(PCRegistry.getTypeAlias(cls), cls); } public void registerAlias(String alias, Class cls) { if (alias == null) return; try { if (alias != null) { List> classes = _aliases.get(alias); if (classes == null) classes = new ArrayList<>(3); if (!classes.contains(cls)) { classes.add(cls); _aliases.put(alias, classes); } } } catch (IllegalStateException ise) { // the class has not been registered to PCRegistry } } /** * Update the list of implementations of base classes and interfaces. */ private void updateImpls(Class cls, Class leastDerived, Class check) { // allow users to query on common non-pc superclasses Class sup = check.getSuperclass(); if (leastDerived == cls && sup != null && sup != Object.class) { addToCollection(_impls, sup, cls, false); updateImpls(cls, leastDerived, sup); } // allow users to query on any implemented interfaces unless defaults // say the user must implement persistent interfaces explicitly in meta if (!_factory.getDefaults().isDeclaredInterfacePersistent()) return; Class[] ints = check.getInterfaces(); for (Class anInt : ints) { // don't map java-standard interfaces if (anInt.getName().startsWith("java.")) continue; // only map least-derived interface implementors if (leastDerived == cls || isLeastDerivedImpl(anInt, cls)) { addToCollection(_impls, anInt, cls, false); updateImpls(cls, leastDerived, anInt); } } } /** * Return true if the given class is the least-derived persistent implementor of the given * interface, false otherwise. */ private boolean isLeastDerivedImpl(Class inter, Class cls) { Class parent = PCRegistry.getPersistentSuperclass(cls); while (parent != null) { if (Arrays.asList(parent.getInterfaces()).contains(inter)) return false; parent = PCRegistry.getPersistentSuperclass(parent); } return true; } /** * Add the given value to the collection cached in the given map under the given key. */ private void addToCollection(Map, Collection>> map, Class key, Class value, boolean inheritance) { if (_locking) { synchronized (map) { addToCollectionInternal(map, key, value, inheritance); } } else { addToCollectionInternal(map, key, value, inheritance); } } private void addToCollectionInternal(Map, Collection>> map, Class key, Class value, boolean inheritance) { Collection> coll = map.get(key); if (coll == null) { if (inheritance) { InheritanceComparator comp = new InheritanceComparator(); comp.setBase(key); coll = new TreeSet>(comp); } else coll = new LinkedList<>(); map.put(key, coll); } coll.add(value); } /** * Puts the meta class corresponding to the given entity class. */ public void setMetaModel(Class m2) { Class cls = _factory.getManagedClass(m2); if (cls != null) _metamodel.put(cls, m2); } /** * Puts the meta class corresponding to the given persistent class. */ public void setMetaModel(ClassMetaData meta, Class m2) { _metamodel.put(meta.getDescribedType(), m2); } /** * Gets the meta class corresponding to the given persistent class. */ public Class getMetaModel(ClassMetaData meta, boolean load) { return getMetaModel(meta.getDescribedType(), load); } /** * Gets the meta class corresponding to the given class. If load is false, returns the meta * class if has been set for the given persistent class earlier. If the load is true then also * attempts to apply the current naming policy to derive meta class name and attempts to load * the meta class. */ public Class getMetaModel(Class entity, boolean load) { if (_metamodel.containsKey(entity)) return _metamodel.get(entity); String m2 = _factory.getMetaModelClassName(entity.getName()); try { ClassLoader loader = AccessController.doPrivileged(J2DoPrivHelper.getClassLoaderAction(entity)); Class m2cls = AccessController.doPrivileged(J2DoPrivHelper.getForNameAction(m2, true, loader)); _metamodel.put(entity, m2cls); return m2cls; } catch (Throwable t) { if (_log.isTraceEnabled()) _log.warn(_loc.get("meta-no-model", m2, entity, t)); } return null; } // ///////////////////////////// // Configurable implementation // ///////////////////////////// @Override public void setConfiguration(Configuration conf) { _conf = (OpenJPAConfiguration) conf; _log = _conf.getLog(OpenJPAConfiguration.LOG_METADATA); _filterRegisteredClasses = _conf.getCompatibilityInstance().getFilterPCRegistryClasses(); _typesWithoutEnhancement = _conf.getTypesWithoutEnhancement(); if (_typesWithoutEnhancement == null || _typesWithoutEnhancement.isEmpty()) { _typesWithoutEnhancement = null; } } @Override public void startConfiguration() { } @Override public void endConfiguration() { initializeMetaDataFactory(); if (_implGen == null) _implGen = new InterfaceImplGenerator(this); if (_preload) { _oids = new HashMap<>(); _impls = new HashMap<>(); _ifaces = new HashMap<>(); _aliases = new HashMap<>(); _pawares = new HashMap<>(); _nonMapped = new HashMap<>(); _subs = new HashMap<>(); // Wait till we're done loading MetaData to flip _lock boolean. } } private void initializeMetaDataFactory() { if (_factory == null) { MetaDataFactory mdf = _conf.newMetaDataFactoryInstance(); if (mdf == null) throw new MetaDataException(_loc.get("no-metadatafactory")); setMetaDataFactory(mdf); } } // //////////////// // Query metadata // //////////////// /** * Return query metadata for the given class, name, and classloader. */ public QueryMetaData getQueryMetaData(Class cls, String name, ClassLoader envLoader, boolean mustExist) { if (_locking) { synchronized (this) { return getQueryMetaDataInternal(cls, name, envLoader, mustExist); } } else { return getQueryMetaDataInternal(cls, name, envLoader, mustExist); } } private QueryMetaData getQueryMetaDataInternal(Class cls, String name, ClassLoader envLoader, boolean mustExist) { QueryMetaData meta = getQueryMetaDataInternal(cls, name, envLoader); if (meta == null) { // load all the metadatas for all the known classes so that // query names are seen and registered resolveAll(envLoader); meta = getQueryMetaDataInternal(cls, name, envLoader); } if (meta == null && mustExist) { if (cls == null) { throw new MetaDataException(_loc.get("no-named-query-null-class", getPersistentTypeNames(false, envLoader), name)); } else { throw new MetaDataException(_loc.get("no-named-query", cls, name)); } } return meta; } /** * Resolve all known metadata classes. */ private void resolveAll(ClassLoader envLoader) { Collection> types = loadPersistentTypes(false, envLoader); for (Class c : types) { getMetaData(c, envLoader, false); } } /** * Return query metadata for the given class, name, and classloader. */ private QueryMetaData getQueryMetaDataInternal(Class cls, String name, ClassLoader envLoader) { if (name == null) return null; // check cache QueryMetaData qm = _queries.get(name); if (qm != null) return qm; // see if factory can figure out a scope for this query if (cls == null) cls = _factory.getQueryScope(name, envLoader); // get metadata for class, which will find queries in metadata file if (cls != null && getMetaData(cls, envLoader, false) != null) { qm = _queries.get(name); if (qm != null) return qm; } if ((_sourceMode & MODE_QUERY) == 0) return null; // not in cache; load _factory.load(cls, MODE_QUERY , envLoader); return _queries.get(name); } /** * Return the cached query metadata. */ public QueryMetaData[] getQueryMetaDatas() { if (_locking) { synchronized (this) { return _queries.values().toArray(new QueryMetaData[_queries.size()]); } } else { return _queries.values().toArray(new QueryMetaData[_queries.size()]); } } public QueryMetaData getCachedQueryMetaData(Class cls, String name) { return getCachedQueryMetaData(name); } /** * Return the cached query metadata for the given name. */ public QueryMetaData getCachedQueryMetaData(String name) { if (_locking) { synchronized (this) { return _queries.get(name); } } else { return _queries.get(name); } } /** * Add a new query metadata to the repository and return it. */ public QueryMetaData addQueryMetaData(Class cls, String name) { if (_locking) { synchronized (this) { QueryMetaData meta = newQueryMetaData(cls, name); _queries.put(name, meta); return meta; } }else{ QueryMetaData meta = newQueryMetaData(cls, name); _queries.put(name, meta); return meta; } } public QueryMetaData addQueryMetaData(QueryMetaData meta) { if (_locking) { synchronized (this) { final QueryMetaData queryMetaData = _queries.get(meta.getName()); return queryMetaData != null ? queryMetaData : _queries.put(meta.getName(), meta); } } else { final QueryMetaData queryMetaData = _queries.get(meta.getName()); return queryMetaData != null ? queryMetaData : _queries.put(meta.getName(), meta); } } /** * Create a new query metadata instance. */ public QueryMetaData newQueryMetaData(Class cls, String name) { QueryMetaData meta = new QueryMetaData(name, _conf.getCompatibilityInstance().getConvertPositionalParametersToNamed()); meta.setDefiningType(cls); return meta; } /** * Remove the given query metadata from the repository. */ public boolean removeQueryMetaData(QueryMetaData meta) { if (meta == null) return false; if (_locking) { synchronized (this) { return _queries.remove(meta.getName()) != null; } } else { return _queries.remove(meta.getName()) != null; } } /** * Remove query metadata for the given class name if in the repository. */ public boolean removeQueryMetaData(Class cls, String name) { if (_locking) { synchronized (this) { if (name == null) return false; return _queries.remove(name) != null; } } else { if (name == null) return false; return _queries.remove(name) != null; } } /** * Searches all cached query metadata by name. */ public QueryMetaData searchQueryMetaDataByName(String name) { return _queries.get(name); } /** * Return a unique key for a given class / name. The class argument can be null. */ protected static Object getQueryKey(Class cls, String name) { if (cls == null) return name; QueryKey key = new QueryKey(); key.clsName = cls.getName(); key.name = name; return key; } // /////////////////// // Sequence metadata // /////////////////// /** * Return sequence metadata for the given name and classloader. */ public SequenceMetaData getSequenceMetaData(String name, ClassLoader envLoader, boolean mustExist) { if (_locking) { synchronized (this) { return getSequenceMetaDataInternal(name, envLoader, mustExist); } } else { return getSequenceMetaDataInternal(name, envLoader, mustExist); } } private SequenceMetaData getSequenceMetaDataInternal(String name, ClassLoader envLoader, boolean mustExist) { SequenceMetaData meta = getSequenceMetaDataInternal(name, envLoader); if (meta == null && SequenceMetaData.NAME_SYSTEM.equals(name)) { if (_sysSeq == null) _sysSeq = newSequenceMetaData(name); return _sysSeq; } if (meta == null && mustExist) throw new MetaDataException(_loc.get("no-named-sequence", name)); return meta; } /** * Used internally by metadata to retrieve sequence metadatas based on possibly-unqualified * sequence name. */ SequenceMetaData getSequenceMetaData(ClassMetaData context, String name, boolean mustExist) { // try with given name MetaDataException e = null; try { SequenceMetaData seq = getSequenceMetaData(name, context.getEnvClassLoader(), mustExist); if (seq != null) return seq; } catch (MetaDataException mde) { e = mde; } // if given name already fully qualified, give up if (name.indexOf('.') != -1) { if (e != null) throw e; return null; } // try with qualified name name = ClassUtil.getPackageName(context.getDescribedType()) + "." + name; try { return getSequenceMetaData(name, context.getEnvClassLoader(), mustExist); } catch (MetaDataException mde) { // throw original exception if (e != null) throw e; throw mde; } } /** * Return sequence metadata for the given name and classloader. */ private SequenceMetaData getSequenceMetaDataInternal(String name, ClassLoader envLoader) { if (name == null) return null; // check cache SequenceMetaData meta = _seqs.get(name); if (meta == null) { // load metadata for registered classes to hopefully find sequence // definition loadRegisteredClassMetaData(envLoader); meta = _seqs.get(name); } return meta; } /** * Return the cached sequence metadata. */ public SequenceMetaData[] getSequenceMetaDatas() { if (_locking) { synchronized (this) { return _seqs.values().toArray(new SequenceMetaData[_seqs.size()]); } } else { return _seqs.values().toArray(new SequenceMetaData[_seqs.size()]); } } /** * Return the cached a sequence metadata for the given name. */ public SequenceMetaData getCachedSequenceMetaData(String name) { if (_locking) { synchronized (this) { return _seqs.get(name); } } else { return _seqs.get(name); } } /** * Add a new sequence metadata to the repository and return it. */ public SequenceMetaData addSequenceMetaData(String name) { if (_locking) { synchronized (this) { SequenceMetaData meta = newSequenceMetaData(name); _seqs.put(name, meta); return meta; } } else { SequenceMetaData meta = newSequenceMetaData(name); _seqs.put(name, meta); return meta; } } /** * Create a new sequence metadata instance. */ protected SequenceMetaData newSequenceMetaData(String name) { return new SequenceMetaData(name, this); } /** * Remove the given sequence metadata from the repository. */ public boolean removeSequenceMetaData(SequenceMetaData meta) { if (meta == null) return false; if (_locking) { synchronized (this) { return _seqs.remove(meta.getName()) != null; } } else { return _seqs.remove(meta.getName()) != null; } } /** * Remove sequence metadata for the name if in the repository. */ public boolean removeSequenceMetaData(String name) { if (name == null) return false; if (_locking) { synchronized (this) { return _seqs.remove(name) != null; } } else { return _seqs.remove(name) != null; } } /** * Whether any system (default) listeners have been registered. Used as a quick test to * determine whether the callback/listener mechanism has been enabled. * @return boolean */ public boolean is_systemListenersActivated() { return _systemListenersActivated; } /** * Add the given system lifecycle listener. */ public void addSystemListener(Object listener) { if (_locking) { synchronized (this) { // copy to avoid issues with ListenerList and avoid unncessary // locking on the list during runtime LifecycleEventManager.ListenerList listeners = new LifecycleEventManager.ListenerList(_listeners); listeners.add(listener); _listeners = listeners; _systemListenersActivated = true; } } else { LifecycleEventManager.ListenerList listeners = new LifecycleEventManager.ListenerList(_listeners); listeners.add(listener); _listeners = listeners; _systemListenersActivated = true; } } /** * Remove the given system lifecycle listener. */ public boolean removeSystemListener(Object listener) { if (_locking) { synchronized (this) { return removeSystemListenerInternal(listener); } } else { return removeSystemListenerInternal(listener); } } private boolean removeSystemListenerInternal(Object listener) { if (!_listeners.contains(listener)) return false; // copy to avoid issues with ListenerList and avoid unncessary // locking on the list during runtime LifecycleEventManager.ListenerList listeners = new LifecycleEventManager.ListenerList(_listeners); listeners.remove(listener); _listeners = listeners; return true; } /** * Return the system lifecycle listeners */ public LifecycleEventManager.ListenerList getSystemListeners() { return _listeners; } /** * Free the resources used by this repository. Closes all user sequences. */ @Override public void close() { if (_locking) { synchronized (this) { closeInternal(); } } else { closeInternal(); } } private void closeInternal() { SequenceMetaData[] smds = getSequenceMetaDatas(); for (SequenceMetaData smd : smds) { smd.close(); } clear(); } /** * Query key struct. */ private static class QueryKey implements Serializable { private static final long serialVersionUID = 1L; public String clsName; public String name; @Override public int hashCode() { int clsHash = (clsName == null) ? 0 : clsName.hashCode(); int nameHash = (name == null) ? 0 : name.hashCode(); return clsHash + nameHash; } @Override public boolean equals(Object obj) { if (obj == this) return true; if (!(obj instanceof QueryKey)) return false; QueryKey qk = (QueryKey) obj; return Objects.equals(clsName, qk.clsName) && Objects.equals(name, qk.name); } } /** * Return XML metadata for a given field metadata * * @return XML metadata */ public XMLMetaData getXMLMetaData(Class cls) { if (_locking) { synchronized (this) { return getXMLMetaDataInternal(cls); } } else { return getXMLMetaDataInternal(cls); } } private XMLMetaData getXMLMetaDataInternal(Class cls) { if (cls == null) { return null; } // check if cached before XMLMetaData xmlmeta = _xmlmetas.get(cls); if (xmlmeta != null) return xmlmeta; // load JAXB XML metadata _factory.loadXMLMetaData(cls); xmlmeta = _xmlmetas.get(cls); return xmlmeta; } /** * Create a new metadata, populate it with default information, add it to the repository, and * return it. * * @param type the access type to use in populating metadata */ public XMLClassMetaData addXMLClassMetaData(Class type) { XMLClassMetaData meta = newXMLClassMetaData(type); if(_locking){ synchronized(this){ _xmlmetas.put(type, meta); } }else{ _xmlmetas.put(type, meta); } return meta; } /** * Return the cached XMLClassMetaData for the given class Return null if none. */ public XMLMetaData getCachedXMLMetaData(Class cls) { return _xmlmetas.get(cls); } /** * Create a new xml class metadata * * @return a XMLClassMetaData */ protected XMLClassMetaData newXMLClassMetaData(Class type) { return new XMLClassMetaData(type); } /** * Create a new xml field meta, add it to the fieldMap in the given xml class metadata * * @return a XMLFieldMetaData */ public XMLFieldMetaData newXMLFieldMetaData(Class type, String name) { return new XMLFieldMetaData(type, name); } public static boolean needsPreload(OpenJPAConfiguration conf) { if (conf == null) return false; Options o = Configurations.parseProperties(Configurations.getProperties(conf.getMetaDataRepository())); if (o.getBooleanProperty(PRELOAD_STR) || o.getBooleanProperty(PRELOAD_STR.toLowerCase())) { return true; } return false; } /** * This private worker ensures that a message is logged when an Entity is enhanced by a version of the enhancer that * is older than the current version. */ private void checkEnhancementLevel(Class cls) { if (!_logEnhancementLevel) { return; } Log log = _conf.getLog(OpenJPAConfiguration.LOG_RUNTIME); boolean res = PCEnhancer.checkEnhancementLevel(cls, _conf.getLog(OpenJPAConfiguration.LOG_RUNTIME)); if (!log.isTraceEnabled() && res) { // Since trace isn't enabled flip the flag so we only log this once. _logEnhancementLevel = false; log.info(_loc.get("down-level-entity")); } } /** * This method returns the ClassMetaData whose described type name matches the typeName parameter. It ONLY operates * against MetaData that is currently known by this repository. Note: This method call WILL NOT resolve any * metadata. */ public ClassMetaData getCachedMetaData(String typeName) { ClassMetaData cmd = _metaStringMap.get(typeName); if (cmd == null) { for (ClassMetaData c : getMetaDatas()) { if (c.getDescribedType().getName().equals(typeName)) { _metaStringMap.put(typeName, c); return c; } } } return cmd; } }




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