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First of all the Boolean type is said to have a default marshal type of a four-byte value. So the following code works:

    struct A 
    { 
        public bool bValue1; 
        public int iValue2; 
    }
    struct B 
    { 
        public int iValue1;
        public bool bValue2; 
    }
    public static void Main()
    {
        int[] rawvalues = new int[] { 2, 4 };

        A a = (A)Marshal.PtrToStructure(GCHandle.Alloc(rawvalues, GCHandleType.Pinned).AddrOfPinnedObject(), typeof(A));
        Assert.IsTrue(a.bValue1 == true);
        Assert.IsTrue(a.iValue2 == 4);
        B b = (B)Marshal.PtrToStructure(GCHandle.Alloc(rawvalues, GCHandleType.Pinned).AddrOfPinnedObject(), typeof(B));
        Assert.IsTrue(b.iValue1 == 2);
        Assert.IsTrue(b.bValue2 == true);
    }

Clearly these structures marshal independently just fine. The values are translated as expected. However, when we combine these structures into a "union" by declaring LayoutKind.Explicit like this:

    [StructLayout(LayoutKind.Explicit)]
    struct Broken
    {
        [FieldOffset(0)]
        public A a;
        [FieldOffset(0)]
        public B b;
    }

We suddenly find ourselves unable to correctly marshal these types. Here is the test code for the above structure and how it fails:

        int[] rawvalues = new int[] { 2, 4 };
        Broken broken = (Broken)Marshal.PtrToStructure(GCHandle.Alloc(rawvalues, GCHandleType.Pinned).AddrOfPinnedObject(), typeof(Broken));

        Assert.IsTrue(broken.a.bValue1 != false);// pass, not false
        Assert.IsTrue(broken.a.bValue1 == true);// pass, must be true?
        Assert.IsTrue(true.Equals(broken.a.bValue1));// FAILS, WOW, WTF?
        Assert.IsTrue(broken.a.iValue2 == 4);// FAILS, a.iValue1 == 1, What happened to 4?
        Assert.IsTrue(broken.b.iValue1 == 2);// pass
        Assert.IsTrue(broken.b.bValue2 == true);// pass

It's very humorous to see this express as true: (a.bValue1 != false && a.bValue1 == true && !true.Equals(a.bValue1))

Of course the bigger problem here is that a.iValue2 != 4, rather the 4 has been changed to 1 (presumably by the overlapped bool).

So the question: Is this a bug, or just failed as designed?

Background: this came from http://stackoverflow.com/questions/1602899

Update: This is even stranger when you use large integer values (> 255) as only the byte that is used for the boolean is being modified to a 1, thus changing 0x0f00 to 0x0f01 for the b.bValue2. For a.bValue1 above it's not translated at all and 0x0f00 provides a false value for a.bValue1.

Update #2:

The most obvious and reasonable solution to the above issue(s) is to use a uint for the marshalling and expose boolean properties instead. Really solving the issue with a 'workaround' is not at question. I'm mostly wondering is this a bug or is this the behavior you would expect?

    struct A 
    { 
        private uint _bValue1;
        public bool bValue1 { get { return _bValue1 != 0; } } 
        public int iValue2; 
    }
    struct B 
    { 
        public int iValue1;
        private uint _bValue2;
        public bool bValue2 { get { return _bValue2 != 0; } } 
    }
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3 Answers 3

up vote 4 down vote accepted

It is working as designed.

Here is what is happening:

Take the new int[] { 2, 4 } and lets marshal it into A, B, Broken, and Broken2. The last is the same as Broken, but with fields' order reversed (first b, then a).

If we marshal the ints into these structures we get the following values in memory:

  • A: 1, 4
  • B: 2, 1
  • Broken: 2, 1
  • Broken2: 1, 4

So what is happening is the following:

  • When the marshaller encounters a boolean, the value of it is: bool = (original != 0);
  • When there are two fields that map into the same memory, the rules of the last field win

So for A, the first int gets converted to 1, for B, the second int gets converted to 1, for Broken, since B is the last field, its rules apply, and hence the second int gets converted to 1. Similarly for Broken2.

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The line commented with 'FAILS, WOW, WTF?' fails because of the way boolean comparison is performed. It is comparing 2 to 1:

IL_007e:  ldc.i4.1
IL_007f:  ldloca.s 3
IL_0081:  ldflda valuetype Test/A Test/Broken::a
IL_0086:  ldfld bool Test/A::bValue1
IL_008b:  ceq

ceq ends up comparing 1 to the byte in bValue, which is 2.

The funny thing is that if (broken.a.bValue1) will test 'true' because it's non-zero.

As far as the other problem (broken.a.iValue2 == 4), it went away when I applied:

[MarshalAs (UnmanagedType.Bool)]

to both boolean fields in the structures. This makes sure the booleans are marshaled as an integer (4 bytes in .NET).

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I just find it interesting that the evaluation of "broken.a.bValue1 == true" is correct when "true.Equals(broken.a.bValue1)" is not. I'll try the MarshalAs (UnmanagedType.Bool) thing. –  csharptest.net Nov 9 '09 at 23:40
    
using MarshalAs(UnmanagedType.Bool) seems to have no effect. –  csharptest.net Nov 10 '09 at 17:33
    
Try this: pastebin.ca/1665189 There's nothing printed in the error output once I comment out the problem that happens because of the IL above. –  Gonzalo Nov 10 '09 at 18:22
    
Agreed, that will 'sorta' work around it. see update for a reasonable solution. Mostly I was just wondering what people though about this behavior? Was it expected or not? –  csharptest.net Nov 10 '09 at 23:03
    
I would expect the true.Equals() call to succeed as the value is non-zero. One problem might be that the valuetype comparison would need to be handled in a different way for booleans, which would probably be a slow down of the common code path executed on every boolean to boolean comparison. –  Gonzalo Nov 10 '09 at 23:09

It would appear earlNameless is correct, as adding another structure of ints:

    struct C
    {
        public int iValue1;
        public int iValue2;
    }

to the end of the union seems to correct at least part of the problem. However, this is still flawed since the boolean will only consider a single-byte value and as demonstrated is not dependable. Finally the best answer I've come up with is to use a custom type for the marshaling.

[Serializable]
[ComVisible(true)]
public struct BOOL : IComparable, IConvertible, IComparable<BOOL>, IEquatable<BOOL>, IComparable<bool>, IEquatable<bool>
{
    private uint _data;

    public BOOL(bool value) { _data = value ? 1u : 0u; }
    public BOOL(int value) { _data = unchecked((uint)value); }
    public BOOL(uint value) { _data = value; }

    private bool Value { get { return _data != 0; } }
    private IConvertible Convertible { get { return _data != 0; } }

    #region IComparable Members
    public int CompareTo(object obj) { return Value.CompareTo(obj); }
    #endregion
    #region IConvertible Members
    public TypeCode GetTypeCode() { return Value.GetTypeCode(); }
    public string ToString(IFormatProvider provider) { return Value.ToString(provider); }
    bool IConvertible.ToBoolean(IFormatProvider provider) { return Convertible.ToBoolean(provider); }
    byte IConvertible.ToByte(IFormatProvider provider) { return Convertible.ToByte(provider); }
    char IConvertible.ToChar(IFormatProvider provider) { return Convertible.ToChar(provider); }
    DateTime IConvertible.ToDateTime(IFormatProvider provider) { return Convertible.ToDateTime(provider); }
    decimal IConvertible.ToDecimal(IFormatProvider provider) { return Convertible.ToDecimal(provider); }
    double IConvertible.ToDouble(IFormatProvider provider) { return Convertible.ToDouble(provider); }
    short IConvertible.ToInt16(IFormatProvider provider) { return Convertible.ToInt16(provider); }
    int IConvertible.ToInt32(IFormatProvider provider) { return Convertible.ToInt32(provider); }
    long IConvertible.ToInt64(IFormatProvider provider) { return Convertible.ToInt64(provider); }
    sbyte IConvertible.ToSByte(IFormatProvider provider) { return Convertible.ToSByte(provider); }
    float IConvertible.ToSingle(IFormatProvider provider) { return Convertible.ToSingle(provider); }
    ushort IConvertible.ToUInt16(IFormatProvider provider) { return Convertible.ToUInt16(provider); }
    uint IConvertible.ToUInt32(IFormatProvider provider) { return Convertible.ToUInt32(provider); }
    ulong IConvertible.ToUInt64(IFormatProvider provider) { return Convertible.ToUInt64(provider); }
    object IConvertible.ToType(Type conversionType, IFormatProvider provider) { return Convertible.ToType(conversionType, provider); }
    #endregion
    #region IComparable<bool> Members
    public int CompareTo(BOOL other) { return Value.CompareTo(other.Value); }
    public int CompareTo(bool other) { return Value.CompareTo(other); }
    #endregion
    #region IEquatable<bool> Members
    public bool Equals(BOOL other) { return Value.Equals(other.Value); }
    public bool Equals(bool other) { return Value.Equals(other); }
    #endregion
    #region Object Override
    public override string ToString() { return Value.ToString(); }
    public override int GetHashCode() { return Value.GetHashCode(); }
    public override bool Equals(object obj) { return Value.Equals(obj); }
    #endregion
    #region implicit/explicit cast operators
    public static implicit operator bool(BOOL value) { return value.Value; }
    public static implicit operator BOOL(bool value) { return new BOOL(value); }
    public static explicit operator int(BOOL value) { return unchecked((int)value._data); }
    public static explicit operator BOOL(int value) { return new BOOL(value); }
    public static explicit operator uint(BOOL value) { return value._data; }
    public static explicit operator BOOL(uint value) { return new BOOL(value); }
    #endregion
    #region +, -, !, ~, ++, --, true, false unary operators overloaded.
    public static BOOL operator !(BOOL b) { return new BOOL(!b.Value); }
    public static bool operator true(BOOL b) { return b.Value; }
    public static bool operator false(BOOL b) { return !b.Value; }
    #endregion
    #region +, -, *, /, %, &, |, ^, <<, >> binary operators overloaded.
    public static BOOL operator &(BOOL b1, BOOL b2) { return new BOOL(b1.Value & b2.Value); }
    public static BOOL operator |(BOOL b1, BOOL b2) { return new BOOL(b1.Value | b2.Value); }
    #endregion
    #region ==, !=, <, >, <=, >= comparison operators overloaded
    public static bool operator ==(BOOL b1, BOOL b2) { return (b1.Value == b2.Value); }
    public static bool operator !=(BOOL b1, BOOL b2) { return (b1.Value != b2.Value); }
    #endregion
}
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