#region Copyright notice and license
// Protocol Buffers - Google's data interchange format
// Copyright 2008 Google Inc. All rights reserved.
// https://developers.google.com/protocol-buffers/
//
// Redistribution and use in source and binary forms, with or without
// modification, are permitted provided that the following conditions are
// met:
//
// * Redistributions of source code must retain the above copyright
// notice, this list of conditions and the following disclaimer.
// * Redistributions in binary form must reproduce the above
// copyright notice, this list of conditions and the following disclaimer
// in the documentation and/or other materials provided with the
// distribution.
// * Neither the name of Google Inc. nor the names of its
// contributors may be used to endorse or promote products derived from
// this software without specific prior written permission.
//
// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
// "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
// LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
// A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
// OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
// SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
// LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
// DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
// THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
// (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
// OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
#endregion
using Google.Protobuf.Collections;
using Google.Protobuf.WellKnownTypes;
using System;
using System.Collections.Generic;
using System.Collections.ObjectModel;
using System.Diagnostics;
using System.Linq;
using System.Threading;
using static Google.Protobuf.Reflection.SourceCodeInfo.Types;
namespace Google.Protobuf.Reflection
{
///
/// The syntax of a .proto file
///
public enum Syntax
{
///
/// Proto2 syntax
///
Proto2,
///
/// Proto3 syntax
///
Proto3,
///
/// An unknown declared syntax
///
Unknown
}
///
/// Describes a .proto file, including everything defined within.
/// IDescriptor is implemented such that the File property returns this descriptor,
/// and the FullName is the same as the Name.
///
public sealed class FileDescriptor : IDescriptor
{
// Prevent linker failures when using IL2CPP with the well-known types.
static FileDescriptor()
{
ForceReflectionInitialization();
ForceReflectionInitialization();
ForceReflectionInitialization();
ForceReflectionInitialization();
ForceReflectionInitialization();
}
private readonly Lazy> declarations;
private FileDescriptor(ByteString descriptorData, FileDescriptorProto proto, IEnumerable dependencies, DescriptorPool pool, bool allowUnknownDependencies, GeneratedClrTypeInfo generatedCodeInfo)
{
SerializedData = descriptorData;
DescriptorPool = pool;
Proto = proto;
Dependencies = new ReadOnlyCollection(dependencies.ToList());
PublicDependencies = DeterminePublicDependencies(this, proto, dependencies, allowUnknownDependencies);
pool.AddPackage(Package, this);
MessageTypes = DescriptorUtil.ConvertAndMakeReadOnly(proto.MessageType,
(message, index) =>
new MessageDescriptor(message, this, null, index, generatedCodeInfo?.NestedTypes[index]));
EnumTypes = DescriptorUtil.ConvertAndMakeReadOnly(proto.EnumType,
(enumType, index) =>
new EnumDescriptor(enumType, this, null, index, generatedCodeInfo?.NestedEnums[index]));
Services = DescriptorUtil.ConvertAndMakeReadOnly(proto.Service,
(service, index) =>
new ServiceDescriptor(service, this, index));
Extensions = new ExtensionCollection(this, generatedCodeInfo?.Extensions);
declarations = new Lazy>(CreateDeclarationMap, LazyThreadSafetyMode.ExecutionAndPublication);
if (!proto.HasSyntax || proto.Syntax == "proto2")
{
Syntax = Syntax.Proto2;
}
else if (proto.Syntax == "proto3")
{
Syntax = Syntax.Proto3;
}
else
{
Syntax = Syntax.Unknown;
}
}
private Dictionary CreateDeclarationMap()
{
var dictionary = new Dictionary();
foreach (var location in Proto.SourceCodeInfo?.Location ?? Enumerable.Empty())
{
var descriptor = FindDescriptorForPath(location.Path);
if (descriptor != null)
{
dictionary[descriptor] = DescriptorDeclaration.FromProto(descriptor, location);
}
}
return dictionary;
}
private IDescriptor FindDescriptorForPath(IList path)
{
// All complete declarations have an even, non-empty path length
// (There can be an empty path for a descriptor declaration, but that can't have any comments,
// so we currently ignore it.)
if (path.Count == 0 || (path.Count & 1) != 0)
{
return null;
}
IReadOnlyList topLevelList = GetNestedDescriptorListForField(path[0]);
DescriptorBase current = GetDescriptorFromList(topLevelList, path[1]);
for (int i = 2; current != null && i < path.Count; i += 2)
{
var list = current.GetNestedDescriptorListForField(path[i]);
current = GetDescriptorFromList(list, path[i + 1]);
}
return current;
}
private DescriptorBase GetDescriptorFromList(IReadOnlyList list, int index)
{
// This is fine: it may be a newer version of protobuf than we understand, with a new descriptor
// field.
if (list == null)
{
return null;
}
// We *could* return null to silently continue, but this is basically data corruption.
if (index < 0 || index >= list.Count)
{
// We don't have much extra information to give at this point unfortunately. If this becomes a problem,
// we can pass in the complete path and report that and the file name.
throw new InvalidProtocolBufferException($"Invalid descriptor location path: index out of range");
}
return list[index];
}
private IReadOnlyList GetNestedDescriptorListForField(int fieldNumber)
{
switch (fieldNumber)
{
case FileDescriptorProto.ServiceFieldNumber:
return (IReadOnlyList) Services;
case FileDescriptorProto.MessageTypeFieldNumber:
return (IReadOnlyList) MessageTypes;
case FileDescriptorProto.EnumTypeFieldNumber:
return (IReadOnlyList) EnumTypes;
default:
return null;
}
}
internal DescriptorDeclaration GetDeclaration(IDescriptor descriptor)
{
DescriptorDeclaration declaration;
declarations.Value.TryGetValue(descriptor, out declaration);
return declaration;
}
///
/// Computes the full name of a descriptor within this file, with an optional parent message.
///
internal string ComputeFullName(MessageDescriptor parent, string name)
{
if (parent != null)
{
return parent.FullName + "." + name;
}
if (Package.Length > 0)
{
return Package + "." + name;
}
return name;
}
///
/// Extracts public dependencies from direct dependencies. This is a static method despite its
/// first parameter, as the value we're in the middle of constructing is only used for exceptions.
///
private static IList DeterminePublicDependencies(FileDescriptor @this, FileDescriptorProto proto, IEnumerable dependencies, bool allowUnknownDependencies)
{
var nameToFileMap = dependencies.ToDictionary(file => file.Name);
var publicDependencies = new List();
for (int i = 0; i < proto.PublicDependency.Count; i++)
{
int index = proto.PublicDependency[i];
if (index < 0 || index >= proto.Dependency.Count)
{
throw new DescriptorValidationException(@this, "Invalid public dependency index.");
}
string name = proto.Dependency[index];
FileDescriptor file;
if (!nameToFileMap.TryGetValue(name, out file))
{
if (!allowUnknownDependencies)
{
throw new DescriptorValidationException(@this, "Invalid public dependency: " + name);
}
// Ignore unknown dependencies.
}
else
{
publicDependencies.Add(file);
}
}
return new ReadOnlyCollection(publicDependencies);
}
///
/// The descriptor in its protocol message representation.
///
internal FileDescriptorProto Proto { get; }
///
/// The syntax of the file
///
public Syntax Syntax { get; }
///
/// The file name.
///
public string Name => Proto.Name;
///
/// The package as declared in the .proto file. This may or may not
/// be equivalent to the .NET namespace of the generated classes.
///
public string Package => Proto.Package;
///
/// Unmodifiable list of top-level message types declared in this file.
///
public IList MessageTypes { get; }
///
/// Unmodifiable list of top-level enum types declared in this file.
///
public IList EnumTypes { get; }
///
/// Unmodifiable list of top-level services declared in this file.
///
public IList Services { get; }
///
/// Unmodifiable list of top-level extensions declared in this file.
/// Note that some extensions may be incomplete (FieldDescriptor.Extension may be null)
/// if this descriptor was generated using a version of protoc that did not fully
/// support extensions in C#.
///
public ExtensionCollection Extensions { get; }
///
/// Unmodifiable list of this file's dependencies (imports).
///
public IList Dependencies { get; }
///
/// Unmodifiable list of this file's public dependencies (public imports).
///
public IList PublicDependencies { get; }
///
/// The original serialized binary form of this descriptor.
///
public ByteString SerializedData { get; }
///
/// Implementation of IDescriptor.FullName - just returns the same as Name.
///
string IDescriptor.FullName => Name;
///
/// Implementation of IDescriptor.File - just returns this descriptor.
///
FileDescriptor IDescriptor.File => this;
///
/// Pool containing symbol descriptors.
///
internal DescriptorPool DescriptorPool { get; }
///
/// Finds a type (message, enum, service or extension) in the file by name. Does not find nested types.
///
/// The unqualified type name to look for.
/// The type of descriptor to look for
/// The type's descriptor, or null if not found.
public T FindTypeByName(String name)
where T : class, IDescriptor
{
// Don't allow looking up nested types. This will make optimization
// easier later.
if (name.IndexOf('.') != -1)
{
return null;
}
if (Package.Length > 0)
{
name = Package + "." + name;
}
T result = DescriptorPool.FindSymbol(name);
if (result != null && result.File == this)
{
return result;
}
return null;
}
///
/// Builds a FileDescriptor from its protocol buffer representation.
///
/// The original serialized descriptor data.
/// We have only limited proto2 support, so serializing FileDescriptorProto
/// would not necessarily give us this.
/// The protocol message form of the FileDescriptor.
/// FileDescriptors corresponding to all of the
/// file's dependencies, in the exact order listed in the .proto file. May be null,
/// in which case it is treated as an empty array.
/// Whether unknown dependencies are ignored (true) or cause an exception to be thrown (false).
/// Details about generated code, for the purposes of reflection.
/// If is not
/// a valid descriptor. This can occur for a number of reasons, such as a field
/// having an undefined type or because two messages were defined with the same name.
private static FileDescriptor BuildFrom(ByteString descriptorData, FileDescriptorProto proto, FileDescriptor[] dependencies, bool allowUnknownDependencies, GeneratedClrTypeInfo generatedCodeInfo)
{
// Building descriptors involves two steps: translating and linking.
// In the translation step (implemented by FileDescriptor's
// constructor), we build an object tree mirroring the
// FileDescriptorProto's tree and put all of the descriptors into the
// DescriptorPool's lookup tables. In the linking step, we look up all
// type references in the DescriptorPool, so that, for example, a
// FieldDescriptor for an embedded message contains a pointer directly
// to the Descriptor for that message's type. We also detect undefined
// types in the linking step.
if (dependencies == null)
{
dependencies = new FileDescriptor[0];
}
DescriptorPool pool = new DescriptorPool(dependencies);
FileDescriptor result = new FileDescriptor(descriptorData, proto, dependencies, pool, allowUnknownDependencies, generatedCodeInfo);
// Validate that the dependencies we've been passed (as FileDescriptors) are actually the ones we
// need.
if (dependencies.Length != proto.Dependency.Count)
{
throw new DescriptorValidationException(
result,
"Dependencies passed to FileDescriptor.BuildFrom() don't match " +
"those listed in the FileDescriptorProto.");
}
result.CrossLink();
return result;
}
private void CrossLink()
{
foreach (MessageDescriptor message in MessageTypes)
{
message.CrossLink();
}
foreach (ServiceDescriptor service in Services)
{
service.CrossLink();
}
Extensions.CrossLink();
}
///
/// Creates a descriptor for generated code.
///
///
/// This method is only designed to be used by the results of generating code with protoc,
/// which creates the appropriate dependencies etc. It has to be public because the generated
/// code is "external", but should not be called directly by end users.
///
public static FileDescriptor FromGeneratedCode(
byte[] descriptorData,
FileDescriptor[] dependencies,
GeneratedClrTypeInfo generatedCodeInfo)
{
ExtensionRegistry registry = new ExtensionRegistry();
registry.AddRange(GetAllExtensions(dependencies, generatedCodeInfo));
FileDescriptorProto proto;
try
{
proto = FileDescriptorProto.Parser.WithExtensionRegistry(registry).ParseFrom(descriptorData);
}
catch (InvalidProtocolBufferException e)
{
throw new ArgumentException("Failed to parse protocol buffer descriptor for generated code.", e);
}
try
{
// When building descriptors for generated code, we allow unknown
// dependencies by default.
return BuildFrom(ByteString.CopyFrom(descriptorData), proto, dependencies, true, generatedCodeInfo);
}
catch (DescriptorValidationException e)
{
throw new ArgumentException($"Invalid embedded descriptor for \"{proto.Name}\".", e);
}
}
private static IEnumerable GetAllExtensions(FileDescriptor[] dependencies, GeneratedClrTypeInfo generatedInfo)
{
return dependencies.SelectMany(GetAllDependedExtensions).Distinct(ExtensionRegistry.ExtensionComparer.Instance).Concat(GetAllGeneratedExtensions(generatedInfo));
}
private static IEnumerable GetAllGeneratedExtensions(GeneratedClrTypeInfo generated)
{
return generated.Extensions.Concat(generated.NestedTypes.Where(t => t != null).SelectMany(GetAllGeneratedExtensions));
}
private static IEnumerable GetAllDependedExtensions(FileDescriptor descriptor)
{
return descriptor.Extensions.UnorderedExtensions
.Select(s => s.Extension)
.Where(e => e != null)
.Concat(descriptor.Dependencies.Concat(descriptor.PublicDependencies).SelectMany(GetAllDependedExtensions))
.Concat(descriptor.MessageTypes.SelectMany(GetAllDependedExtensionsFromMessage));
}
private static IEnumerable GetAllDependedExtensionsFromMessage(MessageDescriptor descriptor)
{
return descriptor.Extensions.UnorderedExtensions
.Select(s => s.Extension)
.Where(e => e != null)
.Concat(descriptor.NestedTypes.SelectMany(GetAllDependedExtensionsFromMessage));
}
///
/// Converts the given descriptor binary data into FileDescriptor objects.
/// Note: reflection using the returned FileDescriptors is not currently supported.
///
/// The binary file descriptor proto data. Must not be null, and any
/// dependencies must come before the descriptor which depends on them. (If A depends on B, and B
/// depends on C, then the descriptors must be presented in the order C, B, A.) This is compatible
/// with the order in which protoc provides descriptors to plugins.
/// The file descriptors corresponding to .
public static IReadOnlyList BuildFromByteStrings(IEnumerable descriptorData)
{
ProtoPreconditions.CheckNotNull(descriptorData, nameof(descriptorData));
// TODO: See if we can build a single DescriptorPool instead of building lots of them.
// This will all behave correctly, but it's less efficient than we'd like.
var descriptors = new List();
var descriptorsByName = new Dictionary();
foreach (var data in descriptorData)
{
var proto = FileDescriptorProto.Parser.ParseFrom(data);
var dependencies = new List();
foreach (var dependencyName in proto.Dependency)
{
FileDescriptor dependency;
if (!descriptorsByName.TryGetValue(dependencyName, out dependency))
{
throw new ArgumentException($"Dependency missing: {dependencyName}");
}
dependencies.Add(dependency);
}
var pool = new DescriptorPool(dependencies);
FileDescriptor descriptor = new FileDescriptor(
data, proto, dependencies, pool,
allowUnknownDependencies: false, generatedCodeInfo: null);
descriptor.CrossLink();
descriptors.Add(descriptor);
if (descriptorsByName.ContainsKey(descriptor.Name))
{
throw new ArgumentException($"Duplicate descriptor name: {descriptor.Name}");
}
descriptorsByName.Add(descriptor.Name, descriptor);
}
return new ReadOnlyCollection(descriptors);
}
///
/// Returns a that represents this instance.
///
///
/// A that represents this instance.
///
public override string ToString()
{
return $"FileDescriptor for {Name}";
}
///
/// Returns the file descriptor for descriptor.proto.
///
///
/// This is used for protos which take a direct dependency on descriptor.proto, typically for
/// annotations. While descriptor.proto is a proto2 file, it is built into the Google.Protobuf
/// runtime for reflection purposes. The messages are internal to the runtime as they would require
/// proto2 semantics for full support, but the file descriptor is available via this property. The
/// C# codegen in protoc automatically uses this property when it detects a dependency on descriptor.proto.
///
///
/// The file descriptor for descriptor.proto.
///
public static FileDescriptor DescriptorProtoFileDescriptor { get { return DescriptorReflection.Descriptor; } }
///
/// The (possibly empty) set of custom options for this file.
///
[Obsolete("CustomOptions are obsolete. Use the GetOptions() method.")]
public CustomOptions CustomOptions => new CustomOptions(Proto.Options?._extensions?.ValuesByNumber);
///
/// The FileOptions, defined in descriptor.proto.
/// If the options message is not present (i.e. there are no options), null is returned.
/// Custom options can be retrieved as extensions of the returned message.
/// NOTE: A defensive copy is created each time this property is retrieved.
///
public FileOptions GetOptions() => Proto.Options?.Clone();
///
/// Gets a single value file option for this descriptor
///
[Obsolete("GetOption is obsolete. Use the GetOptions() method.")]
public T GetOption(Extension extension)
{
var value = Proto.Options.GetExtension(extension);
return value is IDeepCloneable ? (value as IDeepCloneable).Clone() : value;
}
///
/// Gets a repeated value file option for this descriptor
///
[Obsolete("GetOption is obsolete. Use the GetOptions() method.")]
public RepeatedField GetOption(RepeatedExtension extension)
{
return Proto.Options.GetExtension(extension).Clone();
}
///
/// Performs initialization for the given generic type argument.
///
///
/// This method is present for the sake of AOT compilers. It allows code (whether handwritten or generated)
/// to make calls into the reflection machinery of this library to express an intention to use that type
/// reflectively (e.g. for JSON parsing and formatting). The call itself does almost nothing, but AOT compilers
/// attempting to determine which generic type arguments need to be handled will spot the code path and act
/// accordingly.
///
/// The type to force initialization for.
public static void ForceReflectionInitialization() => ReflectionUtil.ForceInitialize();
}
}