I am working on optimization of memory consuming application. In relation to that I have question regarding C# reference type size overhead.

The C# object consumes as many bytes as its fields, plus some additional administrative overhead. I presume that administrative overhead can be different for different .NET versions and implementations.

Do you know what is the size (or maximum size if the overhead is variable) of the administrative overhead for C# objects (C# 4.0 and Windows 7 and 8 environment)?

Does the administrative overhead differs between 32- or 64-bit .NET runtime?

  • 2
    If you knew the answer to this question, what could you do with it?
    – Jon
    Jan 11, 2013 at 20:54
  • 4
    Why not just use a memory profiler? Jan 11, 2013 at 20:59
  • 6
    Do not break the architecture of your app by joining small classes together unless they actually do make sense to be in one class. Small classes are good. Follow @JohnSaunders advice. If you have a memory problem, use a memory profiler. Don't guess. Know. Jan 11, 2013 at 21:13
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    To save memory you might have a look at empty forwarding values geekswithblogs.net/akraus1/archive/2011/08/18/146583.aspx. This comes in handy if you load may similar objects from disk in a streaming fashion. You can later apply many more tricks like reference sharing and other stuff. Jan 11, 2013 at 22:19
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    I am voting to reopen this question because it is not a duplicate. The linked duplicates are about determining the memory size of a class on a specific system at runtime. This question is about the amount of overhead that is included in that size, and how it differs on different systems.
    – HugoRune
    Sep 20, 2016 at 14:58

3 Answers 3


Typically, there is an 8 or 12 byte overhead per object allocated by the GC. There are 4 bytes for the syncblk and 4 bytes for the type handle on 32bit runtimes, 8 bytes on 64bit runtimes. For details, see the "ObjectInstance" section of Drill Into .NET Framework Internals to See How the CLR Creates Runtime Objects on MSDN Magazine.

Note that the actual reference does change on 32bit or 64bit .NET runtimes as well.

Also, there may be padding for types to fit on address boundaries, though this depends a lot on the type in question. This can cause "empty space" between objects as well, but is up to the runtime (mostly, though you can affect it with StructLayoutAttribute) to determine when and how data is aligned.

  • 1
    the TypeHandle (but not the syncblock, I think) are pointers, so it'd be 8 bytes on x64, yeah?
    – JerKimball
    Jan 11, 2013 at 21:01
  • There are ways of optimizing 64-bit pointers down to 32 bits; i.e., if all of the class descriptor info blocks fit into the same 4GB segment, then the runtime interpreter only needs to store an offset into the segment instead of a full-width pointer. Jan 11, 2013 at 21:04
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    @Loadmaster That isn't done, however, at least not in the current runtime. Jan 11, 2013 at 21:08
  • @Loadmaster Yeah, I know what you're talking about, effectively using short-jumps instead of long-jumps, but I believe Reed's correct - the runtime doesn't take this optimization under any circumstances I'm aware of.
    – JerKimball
    Jan 11, 2013 at 21:11
  • I can't really tell from that article what the overhead would be, but what I have found elsewhere says that the answer is wrong: simple-talk.com/dotnet/.net-framework/… stackoverflow.com/questions/10655829/…
    – Guffa
    Jan 12, 2013 at 18:17

There is an article online with the title "The Truth About .NET Objects And Sharing Them Between AppDomains" which shows some rotor source code and some results of experimenting with objects and sharing them between app domains via a plain pointer.


  • 12 bytes for all 32-bit versions of the CLR
  • 24 bytes for all 64-bit versions of the CLR

You can do test this quite easily by adding millions of objects (N) to an array. Since the pointer size is known you can calculate the object size by dividing the value by N.

var initial = GC.GetTotalMemory(true);
const int N = 10 * 1000 * 1000;
var arr = new object[N];
for (int i = 0; i < N; i++)
    arr[i] = new object();

var ObjSize = (GC.GetTotalMemory(false) - initial - N * IntPtr.Size) / N;

to get an approximate value on your .NET platform.

The object size is actually defined to allow the GC to make assumptions about the minimum object size.


// The generational GC requires that every object be at least 12 bytes
// in size.   
#define MIN_OBJECT_SIZE     (2*sizeof(BYTE*) + sizeof(ObjHeader))

For e.g. 32 bit this means that the minimum object size is 12 bytes which do leave a 4-byte hole. This hole is empty for an empty object but if you add e.g. int to your empty class then it is filled and the object size stays at 12 bytes.


There are two types of overhead for an object:

  • Internal data used to handle the object.
  • Padding between data members.

The internal data is two pointers, so in a 32-bit application that is 8 bytes, and in a 64-bit application that is 16 bytes.

Data members are padded so that they start on an even address boundary. If you for example have a byte and an int in the class, the byte is probably padded with three unused bytes so that the int starts on the next machine word boundary.

The layout of the classes is determined by the JIT compiler depending on the architecture of the system (and might vary between framework versions), so it's not known to the C# compiler.


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