wine/DEVELOPERS-HINTS
1998-11-22 16:56:44 +00:00

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This document should help new developers get started. Like all of Wine, it
is a work in progress.
SOURCE TREE STRUCTURE
=====================
The Wine source tree is loosely based on the original Windows modules.
Most of the source is concerned with implementing the Wine API, although
there are also various tools, documentation, sample Winelib code, and
code specific to the binary loader.
Wine API directories:
---------------------
KERNEL:
files/ - file I/O
loader/ - Win16-, Win32-binary loader
memory/ - memory management
msdos/ - DOS features and BIOS calls (interrupts)
scheduler/ - process and thread management
GDI:
graphics/ - graphics drivers
graphics/x11drv/ - X11 display driver
graphics/metafiledrv/ - metafile driver
objects/ - logical objects
USER:
controls/ - built-in widgets
resources/ - built-in dialog resources
windows/ - window management
Other DLLs:
dlls/*/ - Other system DLLs implemented by Wine
Miscellaneous:
misc/ - shell, registry, winsock, etc.
multimedia/ - multimedia driver
ipc/ - SysV IPC based interprocess communication
win32/ - misc Win32 functions
Tools:
------
rc/ - old resource compiler
tools/ - relay code builder, new rc, etc.
documentation/ - some documentation
Binary loader specific directories:
-----------------------------------
debugger/ - built-in debugger
if1632/ - relay code
miscemu/ - hardware instruction emulation
graphics/win16drv/ - Win16 printer driver
Winelib specific directories:
-----------------------------
library/ - Required code for programs using Winelib
libtest/ - Small samples and tests
programs/ - Extended samples / system utilities
IMPLEMENTING NEW API CALLS
==========================
This is the simple version, and covers only Win32. Win16 is slightly uglier,
because of the Pascal heritage and the segmented memory model.
All of the Win32 APIs known to Wine are listed in [relay32/*.spec]. An
unimplemented call will look like (from gdi32.spec)
269 stub PolyBezierTo
To implement this call, you need to do the following four things.
1. Find the appropriate parameters for the call, and add a prototype to
[include/windows.h]. In this case, it might look like
BOOL32 WINAPI PolyBezierTo32(HDC32, LPCVOID, DWORD);
#define PolyBezierTo WINELIB_NAME(PolyBezierTo)
Note the use of the #define for Winelib. See below for discussion of
function naming conventions.
2. Modify the .spec file to tell Wine that the function has an
implementation, what the parameters look like and what Wine function
to use for the implementation. In Win32, things are simple--everything
is 32-bits. However, the relay code handles pointers and pointers to
strings slightly differently, so you should use 'str' and 'wstr' for
strings, 'ptr' for other pointer types, and 'long' for everything else.
269 stdcall PolyBezierTo(long ptr long) PolyBezierTo32
The 'PolyBezierTo32' at the end of the line is which Wine function to use
for the implementation.
3. Implement the function as a stub. Once you add the function to the .spec
file, you must add the function to the Wine source before it will link.
Add a function called 'PolyBezierTo32' somewhere. Good things to put
into a stub:
o a correct prototype, including the WINAPI
o header comments, including full documentation for the function and
arguments
o A FIXME message and an appropriate return value are good things to
put in a stub.
/************************************************************
* PolyBezierTo32 (GDI32.269) Draw many Bezier curves
*
* BUGS
* Unimplemented
*/
BOOL32 WINAPI PolyBezierTo32(HDC32 hdc, LPCVOID p, DWORD count) {
/* tell the user they've got a substandard implementation */
FIXME(gdi, ":(%x,%p,%d): stub\n", hdc, p, count);
/* some programs may be able to compensate,
if they know what happened */
SetLastError(ERROR_CALL_NOT_IMPLEMENTED);
return FALSE; /* error value */
}
4. Implement and test the function.
MEMORY AND SEGMENTS
===================
NE (Win16) executables consist of multiple segments. The Wine loader
loads each segment into a unique location in the Wine processes memory
and assigns a selector to that segment. Because of this, it's not
possible to exchange addresses freely between 16-bit and 32-bit code.
Addresses used by 16-bit code are segmented addresses (16:16), formed
by a 16-bit selector and a 16-bit offset. Those used by the Wine code
are regular 32-bit linear addresses.
There are four ways to obtain a segmented pointer:
- Use the SEGPTR_* macros in include/heap.h (recommended).
- Allocate a block of memory from the global heap and use
WIN16_GlobalLock to get its segmented address.
- Allocate a block of memory from a local heap, and build the
segmented address from the local heap selector (see the
USER_HEAP_* macros for an example of this).
- Declare the argument as 'segptr' instead of 'ptr' in the spec file
for a given API function.
Once you have a segmented pointer, it must be converted to a linear
pointer before you can use it from 32-bit code. This can be done with
the PTR_SEG_TO_LIN() and PTR_SEG_OFF_TO_LIN() macros. The linear
pointer can then be used freely with standard Unix functions like
memcpy() etc. without worrying about 64k boundaries. Note: there's no
easy way to convert back from a linear to a segmented address.
In most cases, you don't need to worry about segmented address, as the
conversion is made automatically by the callback code and the API
functions only see linear addresses. However, in some cases it is
necessary to manipulate segmented addresses; the most frequent cases
are:
- API functions that return a pointer
- lParam of Windows messages that point to a structure
- Pointers contained inside structures accessed by 16-bit code.
It is usually a good practice to used the type 'SEGPTR' for segmented
pointers, instead of something like 'LPSTR' or 'char *'. As SEGPTR is
defined as a DWORD, you'll get a compilation warning if you mistakenly
use it as a regular 32-bit pointer.
STRUCTURE PACKING
=================
Under Windows, data structures are tightly packed, i.e. there is no
padding between structure members. On the other hand, by default gcc
aligns structure members (e.g. WORDs are on a WORD boundary, etc.).
This means that a structure like
struct { BYTE x; WORD y; };
will take 3 bytes under Windows, but 4 with gcc, because gcc will add a
dummy byte between x and y. To have the correct layout for structures
used by Windows code, you need to use the WINE_PACKED attribute; so you
would declare the above structure like this:
struct { BYTE x; WORD y WINE_PACKED; };
You have to do this every time a structure member is not aligned
correctly under Windows (i.e. a WORD not on an even address, or a
DWORD on a address that is not a multiple of 4).
NAMING CONVENTIONS FOR API FUNCTIONS AND TYPES
==============================================
In order to support both Win16 and Win32 APIs within the same source
code, the following convention must be used in naming all API
functions and types. If the Windows API uses the name 'xxx', the Wine
code must use:
- 'xxx16' for the 16-bit version,
- 'xxx32' for the 32-bit version when no ASCII/Unicode strings are
involved,
- 'xxx32A' for the 32-bit version with ASCII strings,
- 'xxx32W' for the 32-bit version with Unicode strings.
You should then use the macros WINELIB_NAME[_AW](xxx) or
DECL_WINELIB_TYPE[_AW](xxx) (defined in include/wintypes.h) to define
the correct 'xxx' function or type for Winelib. When compiling Wine
itself, 'xxx' is _not_ defined, meaning that code inside of Wine must
always specify explicitly the 16-bit or 32-bit version.
If 'xxx' is the same in Win16 and Win32, or if 'xxx' is Win16 only,
you can simply use the same name as Windows, i.e. just 'xxx'. If
'xxx' is Win32 only, you can use 'xxx' if there are no strings
involved, otherwise you must use the 'xxx32A' and 'xxx32W' forms.
Examples:
typedef short INT16;
typedef int INT32;
DECL_WINELIB_TYPE(INT);
typedef struct { /* Win32 ASCII data structure */ } WNDCLASS32A;
typedef struct { /* Win32 Unicode data structure */ } WNDCLASS32W;
typedef struct { /* Win16 data structure */ } WNDCLASS16;
DECL_WINELIB_TYPE_AW(WNDCLASS);
ATOM RegisterClass16( WNDCLASS16 * );
ATOM RegisterClass32A( WNDCLASS32A * );
ATOM RegisterClass32W( WNDCLASS32W * );
#define RegisterClass WINELIB_NAME_AW(RegisterClass)
The Winelib user can then say:
INT i;
WNDCLASS wc = { ... };
RegisterClass( &wc );
and this will use the correct declaration depending on the definition
of the symbols WINELIB and UNICODE.
API ENTRY POINTS
================
Because Win16 programs use a 16-bit stack and because they can only
call 16:16 addressed functions, all API entry points must be at low
address offsets and must have the arguments translated and moved to
Wines 32-bit stack. This task is handled by the code in the "if1632"
directory. To define a new API entry point handler you must place a
new entry in the appropriate API specification file. These files are
named *.spec. For example, the API specification file for the USER
DLL is contained in the file user.spec. These entries are processed
by the "build" program to create an assembly file containing the entry
point code for each API call. The format of the *.spec files is
documented in the file "tools/build-spec.txt".
DEBUG MESSAGES
==============
To display a message only during debugging, you normally write something
like this:
TRACE(win,"abc..."); or
FIXME(win,"abc..."); or
WARN(win,"abc..."); or
ERR(win,"abc...");
depending on the seriousness of the problem. (documentation/degug-msgs
explains when it is appropriate to use each of them)
These macros are defined in include/debug.h. The macro-definitions are
generated by the shell-script tools/make_debug. It scans the source
code for symbols of this forms and puts the necessary macro
definitions in include/debug.h and include/debugdefs.h. These macros
test whether the debugging "channel" associated with the first
argument of these macros (win in the above example) is enabled and
thus decide whether to actually display the text. In addition you can
change the types of displayed messages by supplying the "-debugmsg"
option to Wine. If your debugging code is more complex than just
printf, you can use the symbols TRACE_ON(xxx), WARN_ON(xxx),
ERR_ON(xxx) and FIXME_ON(xxx) as well. These are true when channel xxx
is enabled, either permanent or in the command line. Thus, you can
write:
if(TRACE_ON(win))DumpSomeStructure(&str);
Don't worry about the inefficiency of the test. If it is permanently
disabled (that is TRACE_ON(win) is 0 at compile time), the compiler will
eliminate the dead code.
You have to start tools/make_debug only if you introduced a new macro,
e.g. TRACE(win32).
For more info about debugging messages, read:
documentation/debug-msgs
MORE INFO
=========
1. There is a FREE online version of the MSDN library (including
documentation for the Win32 API) on http://www.microsoft.com/msdn/
2. http://www.sonic.net/~undoc/bookstore.html
3. In 1993 Dr. Dobbs Journal published a column called "Undocumented Corner".
4. You might want to check out BYTE from December 1983 as well :-)