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Warning: This question is a bit heretical... religious programmers always abiding by good practices, please don't read it. :)

Does anyone know why the use of TypedReference is so discouraged (implicitly, by lack of documentation)?

I've found great uses for it, such as when passing generic parameters through functions that shouldn't be generic (when using an object might be overkill or slow, if you need a value type), for when you need an opaque pointer, or for when you need to access an element of an array quickly, whose specs you find at runtime (using Array.InternalGetReference). Since the CLR doesn't even allow incorrect usage of this type, why is it discouraged? It doesn't seem to be unsafe or anything...


Other uses I've found for TypedReference:

"Specializing" generics in C# (this is type-safe):

static void foo<T>(ref T value)
{
    //This is the ONLY way to treat value as int, without boxing/unboxing objects
    if (value is int)
    { __refvalue(__makeref(value), int) = 1; }
    else { value = default(T); }
}

Writing code that works with generic pointers (this is very unsafe if misused, but fast and safe if used correctly):

//This bypasses the restriction that you can't have a pointer to T,
//letting you write very high-performance generic code.
//It's dangerous if you don't know what you're doing, but very worth if you do.
static T Read<T>(IntPtr address)
{
    var obj = default(T);
    var tr = __makeref(obj);

    //This is equivalent to shooting yourself in the foot
    //but it's the only high-perf solution in some cases
    //it sets the first field of the TypedReference (which is a pointer)
    //to the address you give it, then it dereferences the value.
    //Better be 10000% sure that your type T is unmanaged/blittable...
    unsafe { *(IntPtr*)(&tr) = address; }

    return __refvalue(tr, T);
}

Writing a method version of the sizeof instruction, which can be occasionally useful:

static class ArrayOfTwoElements<T> { static readonly Value = new T[2]; }

static uint SizeOf<T>()
{
    unsafe 
    {
        TypedReference
            elem1 = __makeref(ArrayOfTwoElements<T>.Value[0] ),
            elem2 = __makeref(ArrayOfTwoElements<T>.Value[1] );
        unsafe
        { return (uint)((byte*)*(IntPtr*)(&elem2) - (byte*)*(IntPtr*)(&elem1)); }
    }
}

Writing a method that passes a "state" parameter that wants to avoid boxing:

static void call(Action<int, TypedReference> action, TypedReference state)
{
    //Note: I could've said "object" instead of "TypedReference",
    //but if I had, then the user would've had to box any value types
    try
    {
        action(0, state);
    }
    finally { /*Do any cleanup needed*/ }
}

So why are uses like this "discouraged" (by lack of documentation)? Any particular safety reasons? It seems perfectly safe and verifiable if it's not mixed with pointers (which aren't safe or verifiable anyway)...


Update:

Sample code to show that, indeed, TypedReference can be twice as fast (or more):

using System;
using System.Collections.Generic;
static class Program
{
    static void Set1<T>(T[] a, int i, int v)
    { __refvalue(__makeref(a[i]), int) = v; }

    static void Set2<T>(T[] a, int i, int v)
    { a[i] = (T)(object)v; }

    static void Main(string[] args)
    {
        var root = new List<object>();
        var rand = new Random();
        for (int i = 0; i < 1024; i++)
        { root.Add(new byte[rand.Next(1024 * 64)]); }
        //The above code is to put just a bit of pressure on the GC

        var arr = new int[5];
        int start;
        const int COUNT = 40000000;

        start = Environment.TickCount;
        for (int i = 0; i < COUNT; i++)
        { Set1(arr, 0, i); }
        Console.WriteLine("Using TypedReference:  {0} ticks",
                          Environment.TickCount - start);
        start = Environment.TickCount;
        for (int i = 0; i < COUNT; i++)
        { Set2(arr, 0, i); }
        Console.WriteLine("Using boxing/unboxing: {0} ticks",
                          Environment.TickCount - start);

        //Output Using TypedReference:  156 ticks
        //Output Using boxing/unboxing: 484 ticks
    }
}

(Edit: I edited the benchmark above, since the last version of the post used a debug version of the code [I forgot to change it to release], and put no pressure on the GC. This version is a bit more realistic, and on my system, it's more than three times faster with TypedReference on average.)

share|improve this question
    
When I run your example I get completely different results. TypedReference: 203 ticks, boxing/unboxing: 31 ticks. No matter what I try (including different ways to do the timing) the boxing/unboxing is still faster on my system. –  Seph Dec 5 '11 at 12:25
    
@Seph: I just saw your comment. That's very interesting -- it seems to be faster on x64, but slower on x86. Weird... –  Mehrdad Feb 22 '12 at 6:54
    
There is a marked difference between x64, x86, and Any CPU build configurations. x86: boxing/unboxing is slightly faster. x64: TypedReference is ~30% faster. Any CPU: Typed Reference ~10% faster. Any CPU is also the slowest of the above overall, and x86 is the fastest by 3x. –  naasking Mar 20 '13 at 15:05
    
I just tested that benchmark code on my x64 machine under .NET 4.5. I replaced Environment.TickCount with Diagnostics.Stopwatch and went with ms instead of ticks. I ran each build (x86, 64, Any) three times. The best out of three results were as follws: x86: 205/27ms (same result for 2/3 runs on this build) x64: 218/109ms Any: 205/27ms (same result for 2/3 runs on this build) In -all- cases box/unboxing was faster. –  kornman00 Apr 16 '13 at 21:41

2 Answers 2

up vote 30 down vote accepted

Short answer: portability.

While __arglist, __makeref, and __refvalue are language extensions and are undocumented in the C# Language Specification, the constructs used to implement them under the hood (vararg calling convention, TypedReference type, arglist, refanytype, mkanyref, and refanyval instructions) are perfectly documented in the CLI Specification (ECMA-335) in the Vararg library.

Being defined in the Vararg Library makes it quite clear that they are primarily meant to support variable-length argument lists and not much else. Variable-argument lists have little use in platforms that don't need to interface with external C code that uses varargs. For this reason, the Varargs library is not part of any CLI profile. Legitimate CLI implementations may choose not to support Varargs library as it's not included in the CLI Kernel profile:

4.1.6 Vararg

The vararg feature set supports variable-length argument lists and runtime-typed pointers.

If omitted: Any attempt to reference a method with the vararg calling convention or the signature encodings associated with vararg methods (see Partition II) shall throw the System.NotImplementedException exception. Methods using the CIL instructions arglist, refanytype, mkrefany, and refanyval shall throw the System.NotImplementedException exception. The precise timing of the exception is not specified. The type System.TypedReference need not be defined.

Update (reply to GetValueDirect comment):

FieldInfo.GetValueDirect are FieldInfo.SetValueDirect are not part of Base Class Library. Note that there's a difference between .NET Framework Class Library and Base Class Library. BCL is the only thing required for a conforming implementation of the CLI/C# and is documented in ECMA TR/84. (In fact, FieldInfo itself is part of the Reflection library and that's not included in CLI Kernel profile either).

As soon as you use a method outside BCL, you are giving up a bit of portability (and this is becoming increasingly important with the advent of non-.NET CLI implementations like Silverlight and MonoTouch). Even if an implementation wanted to increase compatiblility with the Microsoft .NET Framework Class Library, it could simply provide GetValueDirect and SetValueDirect taking a TypedReference without making the TypedReference specially handled by the runtime (basically, making them equivalent to their object counterparts without the performance benefit).

Had they documented it in C#, it would have had at least a couple implications:

  1. Like any feature, it may become a roadblock to new features, especially since this one doesn't really fit in the design of C# and requires weird syntax extensions and special handing of a type by the runtime.
  2. All implementations of C# have to somehow implement this feature and it's not necessarily trivial/possible for C# implementations that don't run on top of a CLI at all or run on top of a CLI without Varargs.
share|improve this answer
1  
Good arguments for portability, +1. But what about FieldInfo.GetValueDirect and FieldInfo.SetValueDirect? They're part of the BCL, and to use them you need TypedReference, so doesn't that basically force TypedReference to always be defined, regardless of the language spec? (Also, another note: Even if the keywords didn't exist, as long as the instructions existed, you could still access them by dynamically emitting methods... so as long as your platform interops with C libraries, you can use these, whether or not C# has the keywords.) –  Mehrdad Jan 23 '11 at 18:04
    
Oh, and another issue: Even if it's not portable, why did they not document the keywords? At the very least, it's necessary when interoping with C varargs, so at least they could've mentioned it? –  Mehrdad Jan 23 '11 at 18:16
    
@Mehrdad: Updated the post. –  Mehrdad Afshari Jan 24 '11 at 0:10
    
@Mehrdad: Huh, that's interesting. I guess I always assumed that files in the BCL folder of the .NET source are part of the BCL, never really paying attention to the ECMA standardization part. This is pretty convincing... except one little thing: isn't it a bit pointless to even include the (optional) feature in the CLI spec, if there's no documentation on how to use it anywhere? (It would make sense if TypedReference was documented just for one language -- say, managed C++ -- but if no language documents it and so if no one can really use it, then why even bother defining the feature?) –  Mehrdad Jan 24 '11 at 0:33
    
@Mehrdad I suspect the primary motivation was the need for this feature internally for interop (e.g. [DllImport("...")] void Foo(__arglist);) and they implemented it in C# for their own use. Design of the CLI is influenced by a lot of languages (annotations "The Common Language Infrastructure Annotated Standard" demonstrate this fact.) Being a suitable runtime for as many languages as possible, including unforeseen ones, has definitely been a design goal (hence the name) and this is a feature that, for instance, a hypothetical managed C implementation could probably benefit from. –  Mehrdad Afshari Jan 24 '11 at 0:51

Well, I'm no Eric Lippert, so I can't speak directly of Microsoft's motivations, but if I were to venture a guess, I'd say that TypedReference et al. aren't well documented because, frankly, you don't need them.

Every use you mentioned for these features can be accomplished without them, albeit at a performance penalty in some cases. But C# (and .NET in general) isn't designed to be a high-performance language. (I'm guessing that "faster than Java" was the performance goal.)

That's not to say that certain performance considerations haven't been afforded. Indeed, such features as pointers, stackalloc, and certain optimized framework functions exist largely to boost performance in certain situations.

Generics, which I'd say have the primary benefit of type safety, also improve performance similarly to TypedReference by avoiding boxing and unboxing. In fact, I was wondering why you'd prefer this:

static void call(Action<int, TypedReference> action, TypedReference state){
    action(0, state);
}

to this:

static void call<T>(Action<int, T> action, T state){
    action(0, state);
}

The trade-offs, as I see them, are that the former requires fewer JITs (and, it follows, less memory), while the latter is more familiar and, I would assume, slightly faster (by avoiding pointer dereferencing).

I'd call TypedReference and friends implementation details. You've pointed out some neat uses for them, and I think they're worth exploring, but the usual caveat of relying on implementation details applies—the next version may break your code.

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1  
Huh... "you don't need them" -- I should've seen that coming. :-) That's true but it's also not true. What do you define as "need"? Are extension methods really "needed", for example? Regarding your question of using generics in call(): It's because the code isn't always so cohesive -- I was referring more to an example more like that of IAsyncResult.State, where introducing generics would simply not be feasable because all of a sudden it would introduce generics for every class/method involved. +1 for the answer, though... especially for pointing out the "faster than Java" part. :] –  Mehrdad Jan 22 '11 at 5:51
    
Oh, and another point: TypedReference will probably not be undergoing breaking changes anytime soon, given that FieldInfo.SetValueDirect, which is public and probably used by some developers, depends on it. :) –  Mehrdad Jan 22 '11 at 5:56
    
Ah, but you do need extension methods, to support LINQ. Anyway, I'm not really talking about a nice-to-have/need-to-have difference. I wouldn't call TypedReference either of those. (The atrocious syntax and overall unwieldiness disqualify it, in my mind, from the nice-to-have category.) I'd say it's just a good thing to have around when you really need to trim a few microseconds here and there. That said, I thinking of a couple of places in my own code that I'm going to go look at right now, to see if I can optimize them using the techniques you pointed out. –  P Daddy Jan 22 '11 at 16:15
    
Yeah, I guess the syntax is pretty horrific. But once you wrap what you need inside other functions, the results just become (rather beautiful) function calls (e.g. SizeOf<T>(), Read<T>(IntPtr), Write<T>(IntPtr, T), AddressOf<T>(ref T), T2 Cast<T1, T2>(T1), Set<T1, T2>(ref T1, T2), etc.). (Cast() and Set() would be useful for turning the "specializing generics" example into something much less ugly, like Set(ref value, 1) in my example.) And haha okay, let us know here if you manage to optimize anything; it'll be interesting to know. :) –  Mehrdad Jan 22 '11 at 19:01
1  
@Merhdad: I was working on a binary object serializer/deserializer at the time for interprocess/interhost communications (TCP and pipes). My goals were to make it as small (in terms of bytes sent over the wire) and fast (in terms of time spent serializing and deserializing) as possible. I thought I might avoid some boxing and unboxing with TypedReferences, but IIRC, the only place I was able to avoid boxing somewhere was with the elements of single-dimensional arrays of primitives. The slight speed benefit here wasn't worth the complexity it added to the entire project, so I took it out. –  P Daddy Apr 6 '11 at 19:46

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