This question has many duplicates and almost-duplicates on SO, yet almost none of the answers I've seen explore the pitfalls of their chosen solutions.
There are several ways how to associate an arbitrary data pointer with a window, and there are 2 different situations to consider. Depending on the situation, the possibilities are different.
I'm assuming that the problem isn't getting the data pointer into the
WNDPROC initially, but rather, how to store it for subsequent calls.
Method 1: cbWndExtra
When Windows creates an instance of a window, it internally allocates a
WND struct. This struct has a certain size, contains all sorts of window-related things, like its position, its window class, and its current WNDPROC. At the end of this struct, Windows optionally allocates a number of additional bytes that belong to the struct. The number is specified in
WNDCLASSEX.cbWndExtra, which is used in
This implies that this method can only be used if you are the person who registers the window class, i.e. you are authoring the window class.
Applications cannot directly access the
WND struct. Instead, use
GetWindowLong[Ptr]. Non-negative indices access memory inside the extra bytes at the end of the struct. "0" will access the first extra bytes.
This is a clean, and fast way of doing it, if you are authoring the window class. Most Windows internal controls seem to use this method.
Unfortunately, this method does not play so well with dialogs (
DialogBox family). You would have a dialog window class in addition to providing the dialog template, which can become cumbersome to maintain (unless you need to do so for other reasons anyway). If you do want to use it with dialogs, you must specify the window class name in the dialog template, make sure this window class is registered before showing the dialog, and you need to implement a
WNDPROC for the dialog (or use
DefDlgProc). Offset all accesses to the extra memory by
DLGWINDOWEXTRA (including the value of
cbWndExtra). See also below for an extra method exclusive to dialogs.
Method 2: GWLP_USERDATA
WND struct happens to contain one pointer-sized field, which is not used by the system. It is accessed using
GetWindowLongPtr with a negative index. A negative index will access fields inside the
WND structure. Note that according to this, the negative indices do not seem to represent memory offsets, but are arbitrary.
The problem with
GWLP_USERDATA is that it is not clear, and it has not been clear in the past, what exactly the purpose of this field is, and hence, who the owner of this field is. See also this question. The general consensus is that there is no consensus. It is likely that
GWLP_USERDATA was meant to be used by users of the window, and not authors of the window class. This implies that using it inside of the WNDPROC is incorrect, as the WNDPROC is always provided by the window class author.
Most standard windows controls (e.g.
EDIT) adhere to this and do not use
GWLP_USERDATA internally, leaving it free for the window which uses these controls. The problem is that there are WAY too many examples, including on MSDN and on SO, which break this rule and use
GWLP_USERDATA for implementation of the window class. This takes away the cleanest and simplest method for a control user to associate a context pointer with it. At worst, the user code does not know that
GWLP_USERDATA is occupied, and may overwrite it, which likely crashes the application.
Because of this longstanding dispute about the ownership of
GWLP_USERDATA, it is not generally safe to use it. If you are authoring a window class, you probably never should have used it anyway. If you are using a window, you should only do so if you are certain that it is not used by the window class.
Method 3: SetProp
SetProp family of functions implements access to a property table. Each window has its own, independent properties. The key of this table is a string at API surface level, but internally it is really an ATOM.
SetProp can be used by window class authors, and window users, and it has issues too, but they are different from
GWLP_USERDATA. You must make sure that the strings used as the property keys do not collide. The winodw user may not necessarily know what strings the window class author is using internally. Even though conflicts are unlikely, you can avoid them entirely by using a GUID as string, for example. As is evident when looking at the contents of the global atom table, many programs use GUIDs this way.
SetProp must be used with care. Most resources do not explain the pitfalls of this function. Internally, it uses
GlobalAddAtom. This has several implications, which need to be considered when using this function:
Instead of a string, you can use an
ATOM which you yourself have registered with
GlobalAddAtom. This will improve performance;
SetProp internally uses
ATOMs as property keys, never strings. Passing an
ATOM skips the lookup in the global atom table.
The number of possible string atoms in the global atom table is limited to 16384, system-wide. It is a bad idea to use many different property names, let alone if those names are dynamically generated at runtime. Instead, you can use a single property to store a pointer to a structure that contains all the data you need.
If you are using a GUID, it is safe to use the same GUID for every window you are working with, even across different software projects, since every window has its own properties. This way, all of your software will only use up at most two entries in the global atom table (you'll need one GUID for authored window classes, and one for used windows). In fact, it might make sense to define two de-facto standard GUIDs everyone can use for their context pointers.
Because properties use
GlobalAddAtom, you must make sure that the atoms are unregistered. Global atoms are not cleaned up when the process exists and will clog up the global atom table until the operating system is restarted. To do this, you must make sure that
RemoveProp is called. A good place for this is usually
Global atoms are reference-counted. This implies that the counter can overflow at some point. To protect against overflows, once the reference count of an atom reaches 65536, the atom will stay in the atom table forever, and no amount of
GlobalDeleteAtom can get rid of it.
Avoid having many different atom names if you want to use
SetProp. Other than that,
GetProp is a very clean and defensive approach. The dangers of atom leaks could be greatly mitigated if developers agreed upon using the same 2 atom names for all windows, but that is not going to happen.
Method 4: SetWindowSubclass
SetWindowSubclass is meant to allow overriding the
WNDPROC of a specific window, so that you can handle some messages in your own callback, and delegate the rest of the messages to the original
WNDPROC. For example, this can be used to listen for specific key combinations in an
EDIT control, while leaving the rest of the messages to its original implementation.
A convenient side effect of
SetWindowSubclass is that the new, replacement
WNDPROC is not actually a
WNDPROC, but a
SUBCLASSPROC has 2 additional parameters, one of them is
DWORD_PTR dwRefData. This is arbitrary pointer-sized data. The data comes from you, through the last parameter call to
SetWindowSubclass. The data is then passed to every invocation of the replacement
SUBCLASSPROC. If only every
WNDPROC had this parameter!
This method only helps the window class author. During the initial creation of the window (e.g.
WM_CREATE), the window subclasses itself (it can use
lParam for example, or allocate it right there if that's appropriate). The rest of the code that would normally go in
WNDPROC is moved to the replacement
It can even be used in a dialog's own
WM_INITDIALOG message. If the dialog is shown with
DialogParamW, the last parameter can be used as
dwRefData in a
SetWindowSubclass call in the
WM_INITDIALOG message. Then, all the rest of the dialog logic goes in the new
SUBCLASSPROC, which will receive this
dwRefData for every message. Note that this changes semantics slightly. You are now writing at the level of the dialog's window procedure, not the dialog procedure.
SetWindowSubclass uses a property (using
SetProp) whose atom name is
UxSubclassInfo. Every instance of
SetWindowSubclass uses this name, so it will already be in the global atom table on practically any system. It replaces the window's original
WNDPROC with a
MasterSubclassProc. That function uses the data in the
UxSubclassInfo property to get the
dwRefData and call all registered
SUBCLASSPROC functions. This also implies that you should probably not use
UxSubclassInfo as your own property name for anything.
Method 5: Thunk
A thunk is a dynamically generated function that can be executed. Its purpose is to call another function, but with additional parameters that seem to magically come out of nowhere.
This would let you define a function which is like
WNDPROC, but it has one additional parameter. This parameter could be the equivalent of a "this" pointer. Then, when creating the window, you replace the original, stub
WNDPROC with a thunk that calls the real, pseudo-
WNDPROC with an additional parameter.
The way this works is that when the thunk is created, it generates machine code in memory for a load instruction, loading the value of the extra parameter as a constant, and then a jump instruction to the address of the function which would normally require an additional parameter. The thunk itself can then be called as if it were a regular
This method can be used by window class authors and is extremely fast. However, the implementation is not trivial. The
AtlThunk family of functions implements this, but with a quirk. It does not add an extra parameter. Instead, it replaces the
HWND parameter of
WNDPROC with your arbitrary piece of data. However, that is not a big problem since your arbitrary data may contain the
HWND of the window.
Similarly to the
SetWindowSubclass method, you would create the thunk during window creation, using an arbitrary data pointer. Then, replace the window's
WNDPROC with the thunk. All the real work goes in the new, pseudo-
WNDPROC which is targeted by the thunk.
Thunks do not mess with the global atom table at all, and there are no string uniqueness considerations either. However, like everything else that is allocated in heap memory, they must be freed, and after that, the thunk may no longer be called. Since
WM_NCDESTROY is the last message a window receives, this is the place to do that. Otherwise, you must make sure to reinstall the original
WNDPROC when freeing the thunk.
Method 6: Global lookup table
No long explanation needed. In your application, implement a global table where you store
HWNDs as keys and context data as values. You are responsible for cleaning up the table, and, if needed, to make it sufficiently fast.
Window class authors can use private tables for their implementations, and window users can use their own tables to store application-specific information. There are no concerns about atoms or string uniqueness.
These methods work if you are the Window Class Author:
cbWndExtra, (GWLP_USERDATA), SetProp, SetWindowSubclass, Thunk, Global lookup table.
Window Class Author means that you are writing the
WNDPROC function. For example, you may be implementing a custom picture box control, which allows the user to pan and zoom. You may need additional data to store pan/zoom data (e.g. as a 2D transformation matrix), so that you can implement your
WM_PAINT code correctly.
Recommendation: Avoid GWLP_USERDATA because the user code may rely on it; use cbWndExtra if possible.
These methods work if you are the Window User:
GWLP_USERDATA, SetProp, Global lookup table.
Window User means you are creating one or more of the windows and use them in your own application. For example, you may be creating a variable number of buttons dynamically, and each of them is associated with a different piece of data that is relevant when it is being clicked.
Recommendation: Use GWLP_USERDATA if it's a standard Windows control, or you are sure that the control doesn't use it internally.
Extra mention when using dialogs
Dialogs, by default, use a window class that has
cbWndExtra set to
DLGWINDOWEXTRA. It is possible to define your own window class for a dialog, where you allocate, say,
DLGWINDOWEXTRA + sizeof(void*), and then access
GetWindowLongPtrW(hDlg, DLGWINDOWEXTRA). But while doing so you will find yourself having to answer questions you won't like. For example, which
WNDPROC do you use (you can use
DefDlgProc), or which class styles do you use (the default dialogs happen to use
CS_SAVEBITS | CS_DBLCLKS, but good luck finding an authoritative reference).
DLGWINDOEXTRA bytes, dialogs happen to reserve a pointer-sized field, which can be accessed using
GetWindowLongPtr with index
DWLP_USER. This is kind of an additional
GWLP_USERDATA, and, in theory, has the same problems. In practice I have only ever seen this used inside the
DLGPROC which ends up being passed to
DialogBox[Param]. After all, the window user still has
GWLP_USERDATA. So it is probably safe to use for the window class implementation in practically every situation.