third_party/protobuf/3.6.1/csharp/src/Google.Protobuf/Reflection/ReflectionUtil.cs - bazel - Git at Google

 #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.Compatibility;
 using System;
 using System.Reflection;

 namespace Google.Protobuf.Reflection
 {
     /// <summary>
     /// The methods in this class are somewhat evil, and should not be tampered with lightly.
     /// Basically they allow the creation of relatively weakly typed delegates from MethodInfos
     /// which are more strongly typed. They do this by creating an appropriate strongly typed
     /// delegate from the MethodInfo, and then calling that within an anonymous method.
     /// Mind-bending stuff (at least to your humble narrator) but the resulting delegates are
     /// very fast compared with calling Invoke later on.
     /// </summary>
     internal static class ReflectionUtil
     {
         static ReflectionUtil()
         {
             ForceInitialize<string>(); // Handles all reference types
             ForceInitialize<int>();
             ForceInitialize<long>();
             ForceInitialize<uint>();
             ForceInitialize<ulong>();
             ForceInitialize<float>();
             ForceInitialize<double>();
             ForceInitialize<bool>();
             ForceInitialize<int?>();
             ForceInitialize<long?>();
             ForceInitialize<uint?>();
             ForceInitialize<ulong?>();
             ForceInitialize<float?>();
             ForceInitialize<double?>();
             ForceInitialize<bool?>();
             ForceInitialize<SampleEnum>();
             SampleEnumMethod();
         }

         internal static void ForceInitialize<T>() => new ReflectionHelper<IMessage, T>();

         /// <summary>
         /// Empty Type[] used when calling GetProperty to force property instead of indexer fetching.
         /// </summary>
         internal static readonly Type[] EmptyTypes = new Type[0];

         /// <summary>
         /// Creates a delegate which will cast the argument to the type that declares the method,
         /// call the method on it, then convert the result to object.
         /// </summary>
         /// <param name="method">The method to create a delegate for, which must be declared in an IMessage
         /// implementation.</param>
         internal static Func<IMessage, object> CreateFuncIMessageObject(MethodInfo method) =>
             GetReflectionHelper(method.DeclaringType, method.ReturnType).CreateFuncIMessageObject(method);

         /// <summary>
         /// Creates a delegate which will cast the argument to the type that declares the method,
         /// call the method on it, then convert the result to the specified type. The method is expected
         /// to actually return an enum (because of where we're calling it - for oneof cases). Sometimes that
         /// means we need some extra work to perform conversions.
         /// </summary>
         /// <param name="method">The method to create a delegate for, which must be declared in an IMessage
         /// implementation.</param>
         internal static Func<IMessage, int> CreateFuncIMessageInt32(MethodInfo method) =>
             GetReflectionHelper(method.DeclaringType, method.ReturnType).CreateFuncIMessageInt32(method);

         /// <summary>
         /// Creates a delegate which will execute the given method after casting the first argument to
         /// the type that declares the method, and the second argument to the first parameter type of the method.
         /// </summary>
         /// <param name="method">The method to create a delegate for, which must be declared in an IMessage
         /// implementation.</param>
         internal static Action<IMessage, object> CreateActionIMessageObject(MethodInfo method) =>
             GetReflectionHelper(method.DeclaringType, method.GetParameters()[0].ParameterType).CreateActionIMessageObject(method);

         /// <summary>
         /// Creates a delegate which will execute the given method after casting the first argument to
         /// type that declares the method.
         /// </summary>
         /// <param name="method">The method to create a delegate for, which must be declared in an IMessage
         /// implementation.</param>
         internal static Action<IMessage> CreateActionIMessage(MethodInfo method) =>
             GetReflectionHelper(method.DeclaringType, typeof(object)).CreateActionIMessage(method);

         /// <summary>
         /// Creates a reflection helper for the given type arguments. Currently these are created on demand
         /// rather than cached; this will be "busy" when initially loading a message's descriptor, but after that
         /// they can be garbage collected. We could cache them by type if that proves to be important, but creating
         /// an object is pretty cheap.
         /// </summary>
         private static IReflectionHelper GetReflectionHelper(Type t1, Type t2) =>
             (IReflectionHelper) Activator.CreateInstance(typeof(ReflectionHelper<,>).MakeGenericType(t1, t2));

         // Non-generic interface allowing us to use an instance of ReflectionHelper<T1, T2> without statically
         // knowing the types involved.
         private interface IReflectionHelper
         {
             Func<IMessage, int> CreateFuncIMessageInt32(MethodInfo method);
             Action<IMessage> CreateActionIMessage(MethodInfo method);
             Func<IMessage, object> CreateFuncIMessageObject(MethodInfo method);
             Action<IMessage, object> CreateActionIMessageObject(MethodInfo method);
         }

         private class ReflectionHelper<T1, T2> : IReflectionHelper
         {

             public Func<IMessage, int> CreateFuncIMessageInt32(MethodInfo method)
             {
                 // On pleasant runtimes, we can create a Func<int> from a method returning
                 // an enum based on an int. That's the fast path.
                 if (CanConvertEnumFuncToInt32Func)
                 {
                     var del = (Func<T1, int>) method.CreateDelegate(typeof(Func<T1, int>));
                     return message => del((T1) message);
                 }
                 else
                 {
                     // On some runtimes (e.g. old Mono) the return type has to be exactly correct,
                     // so we go via boxing. Reflection is already fairly inefficient, and this is
                     // only used for one-of case checking, fortunately.
                     var del = (Func<T1, T2>) method.CreateDelegate(typeof(Func<T1, T2>));
                     return message => (int) (object) del((T1) message);
                 }
             }

             public Action<IMessage> CreateActionIMessage(MethodInfo method)
             {
                 var del = (Action<T1>) method.CreateDelegate(typeof(Action<T1>));
                 return message => del((T1) message);
             }

             public Func<IMessage, object> CreateFuncIMessageObject(MethodInfo method)
             {
                 var del = (Func<T1, T2>) method.CreateDelegate(typeof(Func<T1, T2>));
                 return message => del((T1) message);
             }

             public Action<IMessage, object> CreateActionIMessageObject(MethodInfo method)
             {
                 var del = (Action<T1, T2>) method.CreateDelegate(typeof(Action<T1, T2>));
                 return (message, arg) => del((T1) message, (T2) arg);
             }
         }

         // Runtime compatibility checking code - see ReflectionHelper<T1, T2>.CreateFuncIMessageInt32 for
         // details about why we're doing this.

         // Deliberately not inside the generic type. We only want to check this once.
         private static bool CanConvertEnumFuncToInt32Func { get; } = CheckCanConvertEnumFuncToInt32Func();

         private static bool CheckCanConvertEnumFuncToInt32Func()
         {
             try
             {
                 // Try to do the conversion using reflection, so we can see whether it's supported.
                 MethodInfo method = typeof(ReflectionUtil).GetMethod(nameof(SampleEnumMethod));
                 // If this passes, we're in a reasonable runtime.
                 method.CreateDelegate(typeof(Func<int>));
                 return true;
             }
             catch (ArgumentException)
             {
                 return false;
             }
         }

         public enum SampleEnum
         {
             X
         }

         // Public to make the reflection simpler.
         public static SampleEnum SampleEnumMethod() => SampleEnum.X;
     }
 }
	#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.Compatibility;
	using System;
	using System.Reflection;

	namespace Google.Protobuf.Reflection
	{
	/// <summary>
	/// The methods in this class are somewhat evil, and should not be tampered with lightly.
	/// Basically they allow the creation of relatively weakly typed delegates from MethodInfos
	/// which are more strongly typed. They do this by creating an appropriate strongly typed
	/// delegate from the MethodInfo, and then calling that within an anonymous method.
	/// Mind-bending stuff (at least to your humble narrator) but the resulting delegates are
	/// very fast compared with calling Invoke later on.
	/// </summary>
	internal static class ReflectionUtil
	{
	static ReflectionUtil()
	{
	ForceInitialize<string>(); // Handles all reference types
	ForceInitialize<int>();
	ForceInitialize<long>();
	ForceInitialize<uint>();
	ForceInitialize<ulong>();
	ForceInitialize<float>();
	ForceInitialize<double>();
	ForceInitialize<bool>();
	ForceInitialize<int?>();
	ForceInitialize<long?>();
	ForceInitialize<uint?>();
	ForceInitialize<ulong?>();
	ForceInitialize<float?>();
	ForceInitialize<double?>();
	ForceInitialize<bool?>();
	ForceInitialize<SampleEnum>();
	SampleEnumMethod();
	}

	internal static void ForceInitialize<T>() => new ReflectionHelper<IMessage, T>();

	/// <summary>
	/// Empty Type[] used when calling GetProperty to force property instead of indexer fetching.
	/// </summary>
	internal static readonly Type[] EmptyTypes = new Type[0];

	/// <summary>
	/// Creates a delegate which will cast the argument to the type that declares the method,
	/// call the method on it, then convert the result to object.
	/// </summary>
	/// <param name="method">The method to create a delegate for, which must be declared in an IMessage
	/// implementation.</param>
	internal static Func<IMessage, object> CreateFuncIMessageObject(MethodInfo method) =>
	GetReflectionHelper(method.DeclaringType, method.ReturnType).CreateFuncIMessageObject(method);

	/// <summary>
	/// Creates a delegate which will cast the argument to the type that declares the method,
	/// call the method on it, then convert the result to the specified type. The method is expected
	/// to actually return an enum (because of where we're calling it - for oneof cases). Sometimes that
	/// means we need some extra work to perform conversions.
	/// </summary>
	/// <param name="method">The method to create a delegate for, which must be declared in an IMessage
	/// implementation.</param>
	internal static Func<IMessage, int> CreateFuncIMessageInt32(MethodInfo method) =>
	GetReflectionHelper(method.DeclaringType, method.ReturnType).CreateFuncIMessageInt32(method);

	/// <summary>
	/// Creates a delegate which will execute the given method after casting the first argument to
	/// the type that declares the method, and the second argument to the first parameter type of the method.
	/// </summary>
	/// <param name="method">The method to create a delegate for, which must be declared in an IMessage
	/// implementation.</param>
	internal static Action<IMessage, object> CreateActionIMessageObject(MethodInfo method) =>
	GetReflectionHelper(method.DeclaringType, method.GetParameters()[0].ParameterType).CreateActionIMessageObject(method);

	/// <summary>
	/// Creates a delegate which will execute the given method after casting the first argument to
	/// type that declares the method.
	/// </summary>
	/// <param name="method">The method to create a delegate for, which must be declared in an IMessage
	/// implementation.</param>
	internal static Action<IMessage> CreateActionIMessage(MethodInfo method) =>
	GetReflectionHelper(method.DeclaringType, typeof(object)).CreateActionIMessage(method);

	/// <summary>
	/// Creates a reflection helper for the given type arguments. Currently these are created on demand
	/// rather than cached; this will be "busy" when initially loading a message's descriptor, but after that
	/// they can be garbage collected. We could cache them by type if that proves to be important, but creating
	/// an object is pretty cheap.
	/// </summary>
	private static IReflectionHelper GetReflectionHelper(Type t1, Type t2) =>
	(IReflectionHelper) Activator.CreateInstance(typeof(ReflectionHelper<,>).MakeGenericType(t1, t2));

	// Non-generic interface allowing us to use an instance of ReflectionHelper<T1, T2> without statically
	// knowing the types involved.
	private interface IReflectionHelper
	{
	Func<IMessage, int> CreateFuncIMessageInt32(MethodInfo method);
	Action<IMessage> CreateActionIMessage(MethodInfo method);
	Func<IMessage, object> CreateFuncIMessageObject(MethodInfo method);
	Action<IMessage, object> CreateActionIMessageObject(MethodInfo method);
	}

	private class ReflectionHelper<T1, T2> : IReflectionHelper
	{

	public Func<IMessage, int> CreateFuncIMessageInt32(MethodInfo method)
	{
	// On pleasant runtimes, we can create a Func<int> from a method returning
	// an enum based on an int. That's the fast path.
	if (CanConvertEnumFuncToInt32Func)
	{
	var del = (Func<T1, int>) method.CreateDelegate(typeof(Func<T1, int>));
	return message => del((T1) message);
	}
	else
	{
	// On some runtimes (e.g. old Mono) the return type has to be exactly correct,
	// so we go via boxing. Reflection is already fairly inefficient, and this is
	// only used for one-of case checking, fortunately.
	var del = (Func<T1, T2>) method.CreateDelegate(typeof(Func<T1, T2>));
	return message => (int) (object) del((T1) message);
	}
	}

	public Action<IMessage> CreateActionIMessage(MethodInfo method)
	{
	var del = (Action<T1>) method.CreateDelegate(typeof(Action<T1>));
	return message => del((T1) message);
	}

	public Func<IMessage, object> CreateFuncIMessageObject(MethodInfo method)
	{
	var del = (Func<T1, T2>) method.CreateDelegate(typeof(Func<T1, T2>));
	return message => del((T1) message);
	}

	public Action<IMessage, object> CreateActionIMessageObject(MethodInfo method)
	{
	var del = (Action<T1, T2>) method.CreateDelegate(typeof(Action<T1, T2>));
	return (message, arg) => del((T1) message, (T2) arg);
	}
	}

	// Runtime compatibility checking code - see ReflectionHelper<T1, T2>.CreateFuncIMessageInt32 for
	// details about why we're doing this.

	// Deliberately not inside the generic type. We only want to check this once.
	private static bool CanConvertEnumFuncToInt32Func { get; } = CheckCanConvertEnumFuncToInt32Func();

	private static bool CheckCanConvertEnumFuncToInt32Func()
	{
	try
	{
	// Try to do the conversion using reflection, so we can see whether it's supported.
	MethodInfo method = typeof(ReflectionUtil).GetMethod(nameof(SampleEnumMethod));
	// If this passes, we're in a reasonable runtime.
	method.CreateDelegate(typeof(Func<int>));
	return true;
	}
	catch (ArgumentException)
	{
	return false;
	}
	}

	public enum SampleEnum
	{
	X
	}

	// Public to make the reflection simpler.
	public static SampleEnum SampleEnumMethod() => SampleEnum.X;
	}
	}