14

I always understood structs (value types) contain exactly the number of bytes as defined in the fields of the structure... however, I did some tests and there seems to be an exception for the empty structs:

public class EmptyStructTest
{
    static void Main(string[] args)
    {
        FindMemoryLoad<FooStruct>((id) => new FooStruct());
        FindMemoryLoad<Bar<FooStruct>>((id) => new Bar<FooStruct>(id));
        FindMemoryLoad<Bar<int>>((id) => new Bar<int>(id));
        FindMemoryLoad<int>((id) => id);
        Console.ReadLine();
    }

    private static void FindMemoryLoad<T>(Func<int, T> creator) where T : new()
    {
        GC.Collect(GC.MaxGeneration);
        GC.WaitForFullGCComplete();
        Thread.MemoryBarrier();
        long start = GC.GetTotalMemory(true);

        T[] ids = new T[10000];
        for (int i = 0; i < ids.Length; ++i)
        {
            ids[i] = creator(i);
        }

        long end = GC.GetTotalMemory(true);
        GC.Collect(GC.MaxGeneration);
        GC.WaitForFullGCComplete();
        Thread.MemoryBarrier();

        Console.WriteLine("{0} {1}", ((double)end-start) / 10000.0, ids.Length);
    }

    public struct FooStruct { }

    public struct Bar<T> where T : struct
    {
        public Bar(int id) { value = id; thing = default(T); }

        public int value;
        public T thing;
    }
}

If you run the program, you'll find that en FooStruct which has obviously 0 bytes of data will consume 1 byte of memory. The reason this is a problem for me is that I want Bar<FooStruct> to consume exactly 4 bytes (because I'm going to allocate it a lot).

Why does it have this behavior and is there a way to fix this (e.g. is there a special thing that consumes 0 bytes-- I'm not looking for a redesign)?

  • P.S.: [StructLayout(LayoutKind.Explicit, Size=0)] gives the same result. – atlaste May 17 '13 at 14:39
  • 1
    Is GC.GetTotalMemory accurate? If so I wasted money on a memory profiler. – paparazzo May 17 '13 at 14:48
  • Why don't you just skip Bar and have FooStruct include the public int value;? – paparazzo May 17 '13 at 15:17
  • @Blam, no it isn't accurate: "Retrieves the number of bytes currently thought to be allocated". – weston May 17 '13 at 15:24
  • 5
    Allowing values to have 0 bytes creates the kind of singularity that swallows black holes. With the array being a clear victim, all of its elements would have the same address. Test this not by using a corner case, test this for the kind of structure you are concerned about. – Hans Passant May 17 '13 at 16:12
11

Summary: An empty struct in .NET consumes 1 byte. You can think of this as packing, since the unnamed byte is only accessible via unsafe code.

More information: if you do all your pointer arithmetic according to values reported by .NET, things work out consistently.

The following example illustrates using adjacent 0-byte structures on the stack, but these observations obviously apply to arrays of 0-byte structures as well.

struct z { };

unsafe static void foo()
{
    var z3 = default(z);
    bool _;
    long cb_pack, Δz, cb_raw;
    var z2 = default(z);    // (reversed since stack offsets are negative)
    var z1 = default(z);
    var z0 = default(z);

    // stack packing differs between x64 and x86
    cb_pack = (long)&z1 - (long)&z0; // --> 1 on x64, 4 on x86

    // pointer arithmetic should give packing in units of z-size
    Δz = &z1 - &z0; // --> 1 on x64, 4 on x86

    // if one asks for the value of such a 'z-size'...
    cb_raw = Marshal.SizeOf(typeof(z));     // --> 1

    // ...then the claim holds up:
    _ = cb_pack == Δz * cb_raw;     // --> true

    // so you cannot rely on special knowledge that cb_pack==0 or cb_raw==0
    _ = &z0 /* + 0 */ == &z1;   // --> false
    _ = &z0 /* + 0 + 0 */ == &z2;   // --> false

    // instead, the pointer arithmetic you meant was:
    _ = &z0 + cb_pack == &z1;   // --> true
    _ = &z0 + cb_pack + cb_pack == &z2; // --> true

    // array indexing also works using reported values
    _ = &(&z0)[Δz] == &z1;  // --> true

    // the default structure 'by-value' comparison asserts that
    // all z instances are (globally) equivalent...
    _ = EqualityComparer<z>.Default.Equals(z0, z1); // --> true

    // ...even when there are intervening non-z objects which
    // would prevent putative 'overlaying' of 0-sized structs:
    _ = EqualityComparer<z>.Default.Equals(z0, z3); // --> true

    // same result with boxing/unboxing
    _ = Object.Equals(z0, z3);  // -> true

    // this one is never true for boxed value types
    _ = Object.ReferenceEquals(z0, z0); // -> false
}

As I mentioned in a comment, @supercat got it right when he noted, "There probably wouldn't have been any problem with designing .NET to allow for zero-length structures from the beginning, but there could be some things that would break if it were to start doing so now."

EDIT: If you need to programmatically distinguish between 0-byte vs. 1-byte value types, you can use the following:

public static bool IsZeroSizeStruct(Type t)
{
    return t.IsValueType && !t.IsPrimitive && 
           t.GetFields((BindingFlags)0x34).All(fi => IsZeroSizeStruct(fi.FieldType));
}

Note that this correctly identifies arbitrarily nested structs where the total size would be zero.

[StructLayout(LayoutKind.Sequential)]
struct z { };
[StructLayout(LayoutKind.Sequential)]
struct zz { public z _z, __z, ___z; };
[StructLayout(LayoutKind.Sequential)]
struct zzz { private zz _zz; };
[StructLayout(LayoutKind.Sequential)]
struct zzzi { public zzz _zzz; int _i; };

/// ...

c = Marshal.SizeOf(typeof(z));      // 1
c = Marshal.SizeOf(typeof(zz));     // 3
c = Marshal.SizeOf(typeof(zzz));    // 3
c = Marshal.SizeOf(typeof(zzzi));   // 8

_ = IsZeroSizeStruct(typeof(z));    // true
_ = IsZeroSizeStruct(typeof(zz));   // true 
_ = IsZeroSizeStruct(typeof(zzz));  // true
_ = IsZeroSizeStruct(typeof(zzzi)); // false

[edit: see comment] What's strange here is that, when nesting 0-byte structs, the single-byte minimum can accumulate (i.e. into 3 bytes for 'zz' and 'zzz') but then suddenly all of that chaff disappears as soon as a single "substantial" field is included.

| improve this answer | |
  • What do you mean, "chaff disappears"? zzzi is 8 bytes, only 4 of which is the "substantial field". The padding didn't disappear, it got padded more to properly align the int. – Ben Voigt Jun 17 '15 at 3:52
  • @BenVoigt Thanks, you are correct. I think I might have mistakenly thought int _i was a long here, therefore occupying the full 8 bytes reported by sizeof zzzi. That would have been mysterious. I've updated my post. – Glenn Slayden Jun 17 '15 at 18:56
9

It's the same reason zero-sized objects aren't allowed in C (or C++): pointer arithmetic in terms of number of elements.

C# supports pointer subtraction in unsafe blocks, defined thus:

Given two expressions, P and Q, of a pointer type T*, the expression P – Q computes the difference between the addresses given by P and Q and then divides that difference by sizeof(T).

Since division by zero is not possible, this implies that sizeof(T) > 0 for all T.

| improve this answer | |
0

Is this what you are looking for?

Null / Empty value for a struct in .Net 1.x

This solution mentions not having any overhead, which I believe is what you are looking for.

Furthermore, Stroustrup talks about why structs aren't empty in C++, now the language is different, but the principle is the same: http://www.stroustrup.com/bs_faq2.html#sizeof-empty

| improve this answer | |
  • 2
    In C++, every object is assumed to have a distinct identity encapsulated by its address. Thus, every object must make the address that is assigned to it unavailable to any other object. The simplest way to do that is to make each object take a minimum of one addressable unit. I don't think such a thing should be necessary in .NET, since I'm unaware of any paradigm of comparing byrefs for equality. – supercat May 17 '13 at 14:52
  • @supercat I thought about that too... but perhaps it does make sense -- after all, how are you supposed to write iterators and so on in unsafe code if the size is really 0. – atlaste May 17 '13 at 15:48
  • @kirk sorry, you're solution is just plain wrong in this scenario. Jon is right though, you should read his comment and his question again. – atlaste May 17 '13 at 15:52
  • @StefandeBruijn: I'm unware of any argument that would compel me to impose a minimum size of struct in the design of .net. Since there's no kind of "primitive only" generic type parameter, I can't see how code could try to loop through a fixed array without knowing the underlying type. Further, even one were writing code to call a method repeatedly with byrefs to consecutive elements in a fixed array, every array in .net has a item-based length which is not dependent upon its physical allocation. for(i=0, ptr=array_data; i<array_length; ptr+=array_item_size, i++) do_something(ref *ptr); – supercat May 17 '13 at 16:00
  • @StefandeBruijn: ...should work just fine even if array_item_size were zero. The ptr value wouldn't go anyplace, but so what? Perhaps one could say that an ability to compare pointers of some type would imply the type must have non-zero size, but I'm not sure when one would really need to compare pointers to things of unknown or generic type. – supercat May 17 '13 at 16:01

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