You don't really need to go through all that work since
EnumWindows (the function in the referenced question) provides a data parameter. You can put whatever value you want there, such as the object reference demonstrated in the answer. Morris's technique is better suited for callback functions that don't provide any general-purpose data parameter.
To adapt the answer to use Morris's code, you'll first need to make sure the signature of the callback method matches the signature of the API's callback function. Since we're calling
EnumWindows, we need a two-argument function returning Bool. The calling convention needs to be stdcall (because Morris's code assumes it, and it's difficult to thunk any other calling convention).
Wnd: HWnd; Param: LParam): Bool; stdcall;
Next, we set up the
TCallbackThunk data structure with all the machine code and the jump offset referring to the intended callback method.
However, we don't use the way Morris described. His code puts the data structure on the stack. That means we're putting executable code on the stack. Modern processors and operating systems don't allow that anymore — the OS will halt your program. We could get around that by calling
VirtualProtect to modify the permissions of the current stack page, allowing it to be executed, but that makes the whole page executable, and we don't want to leave the program open for attack. Instead, we'll allocate a block of memory especially for the thunk record, separate from the stack.
Callback := VirtualAlloc(nil, SizeOf(Callback^),
Callback.POPEDX := $5A;
Callback.MOVEAX := $B8;
Callback.SelfPtr := Self;
Callback.PUSHEAX := $50;
Callback.PUSHEDX := $52;
Callback.JMP := $E9;
Callback.JmpOffset := Integer(@TAutoClickOKThread.cbEnumWindowsClickOK)
- Integer(@Callback.JMP) - 5;
Note that those are 32-bit x86 instructions in that record. I have no idea what the corresponding x86_64 instructions would be.