#region License Information
/* HeuristicLab
* Copyright (C) 2002-2019 Heuristic and Evolutionary Algorithms Laboratory (HEAL)
*
* This file is part of HeuristicLab.
*
* HeuristicLab is free software: you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation, either version 3 of the License, or
* (at your option) any later version.
*
* HeuristicLab is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with HeuristicLab. If not, see .
*/
#endregion
using System;
using System.Collections;
using System.Collections.Generic;
using System.Reflection;
using System.Text;
using HEAL.Attic;
using HeuristicLab.Persistence.Auxiliary;
using HeuristicLab.Persistence.Core.Tokens;
using HeuristicLab.Persistence.Interfaces;
namespace HeuristicLab.Persistence.Core {
///
/// The core hub for serialization. This class transforms an object graph
/// into a tree and later into a stream of serialization tokens using
/// the given configuration.
///
/// Primitive serializers directly format an object to a serializable type.
///
/// Composite serializers decompose an object into other object that are then
/// recursively serialized.
///
/// A constructed serializer is enumerable and continuously analyses
/// and traverses the object graph while the enumerator is iterated
///
public class Serializer : IEnumerable {
private class ReferenceEqualityComparer : IEqualityComparer {
public new bool Equals(object a, object b) {
return Object.ReferenceEquals(a, b);
}
public int GetHashCode(object obj) {
if (obj == null)
return 0;
return obj.GetHashCode();
}
}
private readonly object obj;
private readonly string rootName;
private readonly Dictionary obj2id;
private readonly Dictionary typeCache;
private readonly Configuration configuration;
private readonly bool isTestRun;
private readonly List exceptions;
///
/// Gets or sets a value indicating whether to interleave type information
/// while serializing an object.
///
/// Alternatively the type information can be obtained through the
/// Property after serialization is done.
///
///
/// true if type information should be interleaved; otherwise, false .
///
public bool InterleaveTypeInformation { get; set; }
///
/// Contains a mapping of type id to type and serializer.
///
/// The type cache.
public List TypeCache {
get {
BuildTypeCache();
return externalTypeCache;
}
}
///
/// Contains a list of files (mostly assemblies) that are
/// necessary to deserialize the object graph again.
///
public List RequiredFiles {
get {
BuildTypeCache();
return requiredFiles;
}
}
private List externalTypeCache;
private List requiredFiles;
private void BuildTypeCache() {
externalTypeCache = new List();
Dictionary assemblies = new Dictionary();
foreach (var pair in typeCache) {
string serializer = null;
IPrimitiveSerializer f = configuration.GetPrimitiveSerializer(pair.Key);
if (f != null) {
serializer = f.GetType().AssemblyQualifiedName;
assemblies[f.GetType().Assembly] = true;
} else {
ICompositeSerializer d = configuration.GetCompositeSerializer(pair.Key);
serializer = d.GetType().AssemblyQualifiedName;
assemblies[d.GetType().Assembly] = true;
}
externalTypeCache.Add(new TypeMapping(pair.Value, pair.Key.AssemblyQualifiedName, serializer));
assemblies[pair.Key.Assembly] = true;
}
Dictionary files = new Dictionary();
foreach (Assembly a in assemblies.Keys) {
files[a.CodeBase] = true;
}
requiredFiles = new List(files.Keys);
}
public IEnumerable SerializedTypes {
get {
return typeCache.Keys;
}
}
///
/// Initializes a new instance of the class.
///
/// The object to serialize.
/// The configuration.
public Serializer(object obj, Configuration configuration) :
this(obj, configuration, "ROOT") { }
///
/// Initializes a new instance of the class.
///
/// The object to serialize.
/// The configuration.
/// Name of the root token.
public Serializer(object obj, Configuration configuration, string rootName)
: this(obj, configuration, rootName, false) { }
///
/// Initializes a new instance of the class.
///
/// The object to serialize.
/// The configuration.
/// Name of the root token.
/// Try to complete the whole object graph,
/// don't stop at the first exception
public Serializer(object obj, Configuration configuration, string rootName, bool isTestRun) {
this.InterleaveTypeInformation = false;
this.obj = obj;
this.rootName = rootName;
this.configuration = configuration;
obj2id = new Dictionary(new ReferenceEqualityComparer()) { { new object(), 0 } };
typeCache = new Dictionary();
this.isTestRun = isTestRun;
this.exceptions = new List();
}
///
/// Returns an enumerator that iterates through a collection.
///
///
/// An object that can be used to
/// iterate through the collection.
///
IEnumerator IEnumerable.GetEnumerator() {
return GetEnumerator();
}
///
/// Returns an enumerator that iterates through the serialization tokens.
///
///
/// A that can be used to
/// iterate through serialization tokens.
///
public IEnumerator GetEnumerator() {
var enumerator = Serialize(new DataMemberAccessor(rootName), obj);
if (isTestRun) {
return AddExceptionCompiler(enumerator);
} else {
return enumerator;
}
}
private IEnumerator AddExceptionCompiler(IEnumerator enumerator) {
while (enumerator.MoveNext())
yield return enumerator.Current;
if (exceptions.Count == 1)
throw exceptions[0];
if (exceptions.Count > 1)
throw new PersistenceException("Multiple exceptions during serialization", exceptions);
}
private Stack objectGraphTrace = new Stack();
private IEnumerator Serialize(DataMemberAccessor accessor, object obj) {
object value = accessor.Get(obj);
if (value == null)
return NullReferenceEnumerator(accessor.Name);
Type type = value.GetType();
if (obj2id.ContainsKey(value))
return ReferenceEnumerator(accessor.Name, obj2id[value]);
bool emitTypeInfo = false;
if (!typeCache.ContainsKey(type)) {
typeCache.Add(type, typeCache.Count);
emitTypeInfo = InterleaveTypeInformation;
}
int typeId = typeCache[type];
int? id = null;
if (!type.IsValueType) {
id = obj2id.Count;
obj2id.Add(value, (int)id);
}
try {
objectGraphTrace.Push(accessor.Name);
IPrimitiveSerializer primitiveSerializer = configuration.GetPrimitiveSerializer(type);
if (primitiveSerializer != null)
return PrimitiveEnumerator(
accessor.Name,
typeId,
primitiveSerializer.Format(value),
id,
emitTypeInfo);
ICompositeSerializer compositeSerializer = configuration.GetCompositeSerializer(type);
if (compositeSerializer != null)
return CompositeEnumerator(
accessor.Name,
compositeSerializer.Decompose(value),
id,
typeId,
compositeSerializer.CreateMetaInfo(value),
emitTypeInfo);
throw CreatePersistenceException(type, "Could not determine how to serialize a value.", true);
}
catch (Exception x) {
if (isTestRun) {
exceptions.Add(x);
return new List().GetEnumerator();
} else if (x is PersistenceException) {
throw;
} else {
throw CreatePersistenceException(
type,
string.Format("Uncaught exception during serialization:{0}{1}", Environment.NewLine, x),
false);
}
}
finally {
objectGraphTrace.Pop();
}
}
private PersistenceException CreatePersistenceException(Type type, string message, bool appendConfig) {
StringBuilder sb = new StringBuilder();
sb.Append(message)
.Append("Type was \"")
.Append(type.VersionInvariantName())
.AppendLine("\"")
.Append("object graph location: ")
.AppendLine(string.Join(".", objectGraphTrace.ToArray()));
if (appendConfig) {
sb.AppendLine("No registered primitive serializer for this type:");
foreach (var ps in configuration.PrimitiveSerializers)
sb.Append(ps.SourceType.VersionInvariantName())
.Append(" ---- (")
.Append(ps.GetType().VersionInvariantName())
.AppendLine(")");
sb.AppendLine("Rejected by all composite serializers:");
foreach (var cs in configuration.CompositeSerializers)
sb.Append("\"")
.Append(cs.JustifyRejection(type))
.Append("\" ---- (")
.Append(cs.GetType().VersionInvariantName())
.AppendLine(")");
}
return new PersistenceException(sb.ToString());
}
private IEnumerator NullReferenceEnumerator(string name) {
yield return new NullReferenceToken(name);
}
private IEnumerator ReferenceEnumerator(string name, int id) {
yield return new ReferenceToken(name, id);
}
private IEnumerator PrimitiveEnumerator(string name,
int typeId, ISerialData serializedValue, int? id, bool emitTypeInfo) {
if (emitTypeInfo) {
var mapping = TypeCache[typeId];
yield return new TypeToken(mapping.Id, mapping.TypeName, mapping.Serializer);
}
yield return new PrimitiveToken(name, typeId, id, serializedValue);
}
private IEnumerator CompositeEnumerator(
string name, IEnumerable tags, int? id, int typeId, IEnumerable metaInfo,
bool emitTypeInfo) {
if (emitTypeInfo) {
var mapping = TypeCache[typeId];
yield return new TypeToken(mapping.Id, mapping.TypeName, mapping.Serializer);
}
yield return new BeginToken(name, typeId, id);
bool first = true;
if (metaInfo != null) {
foreach (var tag in metaInfo) {
IEnumerator metaIt = Serialize(new DataMemberAccessor(tag.Name), tag.Value);
while (metaIt.MoveNext()) {
if (first) {
yield return new MetaInfoBeginToken();
first = false;
}
yield return metaIt.Current;
}
}
}
if (!first) {
yield return new MetaInfoEndToken();
}
if (tags != null) {
foreach (var tag in tags) {
IEnumerator it = Serialize(new DataMemberAccessor(tag.Name), tag.Value);
while (it.MoveNext())
yield return it.Current;
}
}
yield return new EndToken(name, typeId, id);
}
}
}