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All structs in C# by default are treated as [StructLayout(LayoutKind.Sequential)]-marked value types. So lets take some number of structs and inspect sizes of this structs:

using System;
using System.Reflection;
using System.Linq;
using System.Runtime.InteropServices;

class Foo
{
  struct E { }
  struct S0 { byte a; }
  struct S1 { byte a; byte b; }
  struct S2 { byte a; byte b; byte c; }
  struct S3 { byte a; int b; }
  struct S4 { int a; byte b; }
  struct S5 { byte a; byte b; int c; }
  struct S6 { byte a; int b; byte c; }
  struct S7 { int a; byte b; int c; }
  struct S8 { byte a; short b; int c; }
  struct S9 { short a; byte b; int c; }
  struct S10 { long a; byte b; }
  struct S11 { byte a; long b; }
  struct S12 { byte a; byte b; short c; short d; long e; }
  struct S13 { E a; E b; }
  struct S14 { E a; E b; int c; }
  struct S15 { byte a; byte b; byte c; byte d; byte e; }
  struct S16 { S15 b; byte c; }
  struct S17 { long a; S15 b; }
  struct S18 { long a; S15 b; S15 c; }
  struct S19 { long a; S15 b; S15 c; E d; short e; }
  struct S20 { long a; S15 b; S15 c; short d; E e; }

  static void Main()
  {
    Console.WriteLine("name: contents => size\n");
    foreach (var type in typeof(Foo).GetNestedTypes(BindingFlags.NonPublic))
    {
      var fields = type.GetFields(BindingFlags.NonPublic | BindingFlags.Instance);
      Console.WriteLine("{0}: {2} => {1}", type.Name, Marshal.SizeOf(type),
        string.Join("+", fields.Select(_ => Marshal.SizeOf(_.FieldType))));
    }
  }
}

Output is (the same on x86/x64):

name: contents => size

E:  => 1
S0: 1 => 1
S1: 1+1 => 2
S2: 1+1+1 => 3
S3: 1+4 => 8
S4: 4+1 => 8
S5: 1+1+4 => 8
S6: 1+4+1 => 12
S7: 4+1+4 => 12
S8: 1+2+4 => 8
S9: 2+1+4 => 8
S10: 8+1 => 16
S11: 1+8 => 16
S12: 1+1+2+2+8 => 16
S13: 1+1 => 2
S14: 1+1+4 => 8
S15: 1+1+1+1+1 => 5
S16: 5+1 => 6
S17: 8+5 => 16
S18: 8+5+5 => 24
S19: 8+5+5+1+2 => 24
S20: 8+5+5+2+1 => 24

Looking at this results I can't understand the layout (fields aligning and total size) ruleset CLR used for sequential structs. Can somebody explain me this behavior?

share|improve this question
3  
Are you asking for the ruleset used by the CLR for structs in managed space (which is an implementation detail) or the ruleset used by the marshaller when marshalling structs between managed an unmanaged space (Marshal.SizeOf returns the size of a struct after marshalling, not of the struct in managed space)? –  dtb Nov 25 '11 at 0:49
    
Narrow it down a bit, which particular results are unexpected? –  Hans Passant Nov 25 '11 at 1:42
    
@dtb with sequential layout this two things are completely the same. Marshal.SizeOf() gives completely the same sizes, as C# sizeof operator returns. –  ControlFlow Nov 25 '11 at 6:48
1  
@ControlFlow: They're not necessarily the same: For example, a CLR bool takes up one byte; a marshalled bool requires 4 bytes. –  LukeH Nov 25 '11 at 8:56
    
@ControlFlow: another example: a CLR char takes up two bytes; Marshal.SizeOf(typeof(char)) returns 1. –  dtb Nov 25 '11 at 9:22

1 Answer 1

up vote 9 down vote accepted

All the fields are aligned depending on their type. The native types (int, byte, etc.) are all aligned by their size. For example, an int will always be at a multiple of 4 bytes in, while a byte can be anywhere.

If smaller fields come before an int, padding will be added if necessary to ensure the int is properly aligned to 4 bytes. This is why S5 (1+1+4 = 8) and S8 (1+2+4 = 8) will have padding and end up the same size:

[1][1][ ][ ][4] // S5
[1][ ][ 2  ][4] // S8

Additionally, the struct itself inherits the alignment of its most-aligned field (ie. for S5 and S8, int is the most-aligned field, so both of them have an alignment of 4). Alignment is inherited like this so that when you have an array of structs, all the fields in all the structs will be properly aligned. So, 4+2 = 8.

[4][2][ ][ ] // starts at 0
[4][2][ ][ ] // starts at 8
[4][2][ ][ ] // starts at 16

Notice the 4 is always aligned by 4. Without inheriting from the most-aligned field, every other element in an array would have its int aligned by 6 bytes instead of 4:

[4][2] // starts at 0
[4][2] // starts at 6 -- the [4] is not properly aligned!
[4][2] // starts at 12

This would be very bad because not all architectures allow reading from unaligned memory addresses, and even the ones that do have a (potentially quite large, if on a cache line boundary) performance penalty for doing it. Proper alignment is very important!

You will often see clever native coders keep all of this in mind while laying out their structures, sorting all fields from largest to smallest in an effort to keep padding, and thus struct size, to a minimum.

share|improve this answer
    
Thany you! But what about fields of non-native types? –  ControlFlow Nov 25 '11 at 6:53
    
If struct inherits alignment from the most-aligned field, why struct S22 { S16 a; S15 b; } produces 6 + 5 => 11 output? most-aligned field is a of size 6, isn't it? –  ControlFlow Nov 25 '11 at 11:15
    
non-native types inherit the alignment of their most-aligned field. So S15 is aligned by 1, because its most-aligned field is of type byte. S16 is also aligned by 1, because it only contains a S15 and byte. –  Cory Nelson Nov 25 '11 at 21:46
    
Another reason for alignment is because of multithreading. Generally speaking* a misaligned int is not guaranteed to be updated in a single atomic operation on x86 or most other platforms. That means if Thread A writes a new value to int X at the same time Thread B is reading int X, Thread B might get a mangled value made up of half the bits of the old value and half the bits of the new value. Correctly aligned 16/32/64bit values are written in a single atomic operation (8bit values are always 'correctly aligned'). –  David Apr 3 '13 at 16:32

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