561 lines
22 KiB
Plaintext
561 lines
22 KiB
Plaintext
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Specmaker - A Wine DLL tool
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---------------------------
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Background
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----------
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Most of the functions available in Windows, and in Windows applications, are
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made available to applications from DLL's. Wine implements the Win32 API by
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providing replacement's for the essential Windows DLLs in the form of Unix
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shared library (.so) files, and provides a tool, winebuild, to allow Winelib
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applications to link to functions exported from shared libraries/DLLs.
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The first thing to note is that there are many DLLs that aren't yet
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implemented in Wine. Mostly this doesn't present a problem because the native
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Win32 versions of lots of DLLs can be used without problems, at least on
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x86 platforms. However, one of Wine's goals is the eventual replacement of
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every essential O/S DLL so that the whole API is implemented. This not only
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means that a copy of the real O/S is not needed, but also that non-x86
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platforms can run most Win32 programs after recompiling.
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The second thing to note is that applications commonly use their own or 3rd
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party DLLs to provide functionality. In order to call these functions with
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a Winelib program, some 'glue' is needed. This 'glue' comes in the form of
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a .spec file. The .spec file, along with some dummy code, is used to create
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a Wine .so corresponding to the Windows DLL. The winebuild program can then
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resolve calls made to DLL functions to call your dummy DLL. You then tell
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Wine to only use the native Win32 version of the DLL, and at runtime your
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calls will be made to the Win32 DLL. If you want to reimplement the dll,
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you simply add the code for the DLL calls to your stub .so, and then tell
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Wine to use the .so version instead [1].
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These two factors mean that if you are:
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A: Reimplementing a Win32 DLL for use within Wine, or
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B: Compiling a Win32 application with Winelib that uses x86 DLLs
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Then you will need to create a .spec file (amongst other things). If you
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won't be doing either of the above, then you won't need specmaker.
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Creating a .spec file is a labour intensive task during which it is easy
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to make a mistake. The idea of specmaker is to automate this task and create
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the majority of the support code needed for your DLL. In addition you can
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have specmaker create code to help you reimplement a DLL, by providing
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tracing of calls to the DLL, and (in some cases) automatically determining
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the parameters, calling conventions, and return values of the DLLs functions.
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You can think of specmaker as somewhat similar to the IMPLIB tool when
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only its basic functionality is used.
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Usage
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-----
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Specmaker is a command line tool. Running it with no arguments or passing
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it '-h' on the command line lists the available options:
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Usage: specmaker [options] -d dll
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Options:
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-d dll Use dll for input file (mandatory)
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-h Display this help message
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-I dir Look for prototypes in 'dir' (implies -c)
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-o name Set the output dll name (default: dll)
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-c Generate skeleton code (requires -I)
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-t TRACE arguments (implies -c)
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-f dll Forward calls to 'dll' (implies -t)
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-D Generate documentation
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-C Assume __cdecl calls (default: __stdcall)
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-s num Start prototype search after symbol 'num'
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-e num End prototype search after symbol 'num'
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-q Don't show progress (quiet).
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-v Show lots of detail while working (verbose).
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Basic options
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-------------
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OPTION: -d dll Use dll for input file (mandatory)
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The -d option tells specmaker which DLL you want to create a .spec file
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for. You *must* give this option.
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16 bit DLL's are not currently supported (Note that Winelib is intended
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only for Win32 programs).
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OPTION: -o name Set the output dll name (default: dll)
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By default, if specmaker is run on DLL 'foo', it creates files called
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'foo.spec', 'foo_main.c' etc, and prefixes any functions generated
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with 'FOO_'. If '-o bar' is given, these will become 'bar.spec',
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'bar_main.c' and 'BAR_' respectively.
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This option is mostly useful when generating a forwarding DLL. See below
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for more information.
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OPTION: -q Don't show progress (quiet).
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-v Show lots of detail while working (verbose).
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There are 3 levels of output while specmaker is running. The default level,
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when neither -q or -v are given, prints the number of exported functions
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found in the dll, followed by the name of each function as it is processed,
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and a status indication of whether it was processed OK. With -v given, a
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lot of information is dumped while specmaker works: this is intended to help
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debug any problems. Giving -q means nothing will be printed unless a fatal
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error occurs, and could be used when calling specmaker from a script.
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OPTION: -C Assume __cdecl calls (default: __stdcall)
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This option determines the default calling convention used by the functions
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in the DLL. If specbuild cannot determine the convention, __stdcall is
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used by default, unless this option has been given.
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Unless -q is given, a warning will be printed for every function that
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specmaker determines the calling convention for and which does not match
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the assumed calling convention.
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Generating stub DLLS
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--------------------
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If all you want to do is generate a stub DLL to allow you to link your
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Winelib application to an x86 DLL, the above options are all you need.
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As an example, lets assume the application you are porting uses functions
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from a 3rd party dll called 'zipextra.dll', and the functions in the DLL
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use the __stdcall calling convention. Copy zipextra.dll to an empty directory,
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change to it, and run specmaker as follows:
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specmaker -d zipextra (Note: this assumes specmaker is in your path)
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The output will look something like the following:
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22 exported symbols in DLL ...
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Export 1 - '_OpenZipFile' ... [Ignoring]
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Export 2 - '_UnZipFile' ... [Ignoring]
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...
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"[Ignoring]" Just tells you that specmaker isn't trying to determine the
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parameters or return types of the functions, its just creating stubs.
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The following files are created:
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zipextra.spec
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This is the .spec file. Each exported function is listed as a stub:
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@ stub _OpenZipFile
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@ stub _UnZipFile
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...
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This means that winebuild will generate dummy code for this function. That
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doesn't concern us, because all we want is for winebuild to allow the
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symbols to be resolved. At run-time, the functions in the native DLL will
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be called; this just allows us to link.
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zipextra_dll.h zipextra_main.c
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These are source code files containing the minimum set of code to build
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a stub DLL. The C file contains one function, ZIPEXTRA_Init, which does
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nothing.
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Makefile.in
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This is a template for 'configure' to produce a makefile. It is designed
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for a DLL that will be inserted into the Wine source tree. If your DLL
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will not be part of Wine, or you don't wish to build it this way,
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you should look at the Wine tool 'winemaker' to generate a DLL project.
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FIXME: winemaker could run this tool automatically when generating projects
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that use extra DLL's (*.lib in the "ADD LINK32" line in .dsp) ....
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zipextra_install
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A shell script for adding zipextra to the Wine source tree (see below).
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Inserting a stub DLL into the Wine tree
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---------------------------------------
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To build your stub DLL as part of Wine, do the following:
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chmod a+x ./zipextra_install
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./zipextra_install <wine-path>
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cd <wine-path>
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autoconf
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./configure
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make depend && make
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make install
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Your application can now link with the DLL.
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NOTE: **DO NOT** submit patches to Wine for 3rd party DLLs! Building DLLs
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into your copy of the tree is just a simple way for you to link. When
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you release your application you won't be distributing the Unix .so
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anyway, just the Win32 DLL. As you update your version of Wine
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you can simply re-run the procedure above (Since no patches are
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involved, it should be pretty resiliant to changes).
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Advanced Options
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----------------
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This section discusses features of specmaker that are useful to Wine Hackers
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or developers looking to reimplement a Win32 DLL for Unix. Using these
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features means you will need to be able to resolve compilation problems and
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have a general understanding of Wine programming.
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OPTION: -I dir Look for prototypes in 'dir' (implies -c)
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For all advanced functionality, you must give specmaker a directoryor file that
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contains prototypes for the DLL. In the case of Windows DLLs, this could be
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either the standard include directory from your compiler, or an SDK include
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directory. If you have a text document with prototypes (such as documentation)
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that can be used also, however you may need to delete some non-code lines to
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ensure that prototypes are parsed correctly.
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The 'dir' argument can also be a file specification (e.g. "include/*"). If
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it contains wildcards you must quote it to prevent the shell from expanding it.
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If you have no prototypes, specify /dev/null for 'dir'. Specmaker may still
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be able to generate some working stub code for you.
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Once you have created your DLL, if you generated code (see below), you can
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backup the DLL header file created and use it for rebuilding the DLL (you
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should remove the DLLNAME_ prefix from the prototypes to make this work). This
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allows you to add names to the function arguments, for example, so that the
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comments and prototype in the regenerated DLL will be clearer.
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Specmaker searches for prototypes using 'grep', and then retrieves each
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prototype by calling 'function_grep.pl', a Perl script. When you pass the -v
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option on the command line, the calls to both of these programs are logged.
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This allows you to see where each function definition has come from. Should
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specmaker take an excessively long time to locate a prototype, you can check
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that it is searching the right files; you may want to limit the number of files
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searched if locating the prototype takes too long.
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You can compile function_grep.pl for a slight increase in performance; see
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'man perlcc' for details.
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OPTION: -s num Start prototype search after symbol 'num'
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-e num End prototype search after symbol 'num'
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By passing the -s or -e options you can have specmaker try to generate code
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for only some functions in your DLL. This may be used to generate a single
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function, for example, if you wanted to add functionality to an existing DLL.
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They is also useful for debugging problems, in conjunction with -v.
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OPTION: -D Generate documentation
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By default, specmaker generates a standard comment at the header of each
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function it generates. Passing this option makes specmaker output a full
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header template for standard Wine documentation, listing the parameters
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and return value of the function.
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OPTION: -c Generate skeleton code (requires -I)
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This option tells specmaker that you want to create function stubs for
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each function in the DLL. This is the most basic level of code generation.
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As specmaker reads each exported symbol from the source DLL, it first tries
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to demangle the name. If the name is a C++ symbol, the arguments, class and
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return value are all encoded into the symbol name. Specmaker converts this
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information into a C function prototype. If this fails, the file(s) specified
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in the -I argument are scanned for a function prototype. If one is found it
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is used for the next step of the process, code generation.
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Note: C++ name demangling is currently under development. Since the algorithm
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used is not documented, it must be decoded. Many simple prototypes are already
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working however.
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If specmaker does not find a prototype, it emits code like the following:
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In the .spec file:
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@stub _OpenZipFile
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in the header file:
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/* __cdecl ZIPEXTRA__OpenZipFile() */
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in the C source file:
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/*********************************************************************
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* _OpenZipFile (ZIPEXTRA.@)
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*
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*/
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#if 0
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__stdcall ZIPEXTRA__OpenZipFile()
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{
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/* '@Stubbed'ed in .spec */
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}
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#endif
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If a prototype is found, or correctly demangled, the following is emitted:
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.spec:
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@ stdcall _OpenZipFile ZIPEXTRA__OpenZipFile
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.h:
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BOOL __stdcall ZIPEXTRA__OpenZipFile(LPCSTR pszFileName);
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.c:
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BOOL __stdcall ZIPEXTRA__OpenZipFile(LPCSTR pszFileName)
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{
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TRACE("stub");
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return 0;
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}
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Note that if the prototype does not contain argument names, specmaker will
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add them following the convention arg0, arg1 ... argN. If the function is
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demangled C++, the first argument will be called '_this' if an implicit this
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pointer is passed (i.e. the function is a non-static class member function).
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OPTION: -t TRACE arguments (implies -c)
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This option produces the same code as -c, except that arguments are printed
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out when the function is called, so the FIXME in the above example becomes:
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FIXME("(%s) stub", pszFileName);
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Structs that are passed by value are printed as "struct", and functions
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that take variable argument lists print "...".
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OPTION: -f dll Forward calls to 'dll' (implies -t)
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This is the most complicated level of code generation. The same code is
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generated as -t, however support is added for forwarding calls to another
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DLL. The DLL to forward to is given as 'dll'. Lets suppose we built the
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examples above using "-f real_zipextra". The code generated will look like
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the following:
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.spec
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As for -c, except if a function prototype was not found:
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@ forward _OpenZipFile real_zipextra._OpenZipFile
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In this case the function is forwarded to the destination DLL rather
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than stubbed.
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.h
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As for -c.
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.c
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A variable "hDLL" is added to hold a pointer to the DLL to forward to, and
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the initialisation code in ZIPEXTRA_Init is changed to load and free the
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forward DLL automatically:
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HMODULE hDLL = 0; /* DLL to call through to */
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BOOL WINAPI ZIPEXTRA_Init(HINSTANCE hinstDLL, DWORD fdwReason, LPVOID lpvReserved)
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{
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TRACE("(0x%08x, %ld, %p)\n", hinstDLL, fdwReason, lpvReserved);
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if (fdwReason == DLL_PROCESS_ATTACH)
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{
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hDLL = LoadLibraryA( "real_zipextra" );
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TRACE ("Forwarding DLL (real_zipextra) loaded\n" );
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}
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else if (fdwReason == DLL_PROCESS_DETACH)
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{
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FreeLibrary( hDLL );
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TRACE ("Forwarding DLL (real_zipextra) freed\n" );
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}
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return TRUE;
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}
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The stub function is changed to call the forwarding DLL and return that value.
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BOOL __stdcall ZIPEXTRA__OpenZipFile(LPCSTR pszFileName)
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{
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BOOL (__stdcall *pFunc)(LPCSTR) = (void*)GetProcAddress(hDLL,"_OpenZipFile");
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BOOL retVal;
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TRACE("((LPCSTR)%s) stub", pszFileName);
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retVal = pFunc(pszFileName);
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TRACE("returned (%ld)\n",(LONG)retVal));
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return retVal;
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}
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This allows you to investigate the workings of a DLL without interfering in
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its operation in any way (unless you want to).
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In the example I have been using, we probably should have used the -o option
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to change the ouput name of our DLL to something else, and used the -f
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option to forward to the real zipextra DLL:
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specmaker -d zipextra -f zipextra -o myzipextra -I "~/zipextra/include/*h"
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Then in the .spec file for our Winelib application, we add the line:
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import myzipextra
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When we build our application, winebuild resolves the calls to our Unix .so.
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As our application runs we can see the values of all parameters passed to
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the DLL, and any values returned, without having to write code to dump
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them ourselves (see below for a better way to wrap a DLL for forwarding).
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This isn't a very realistic example of the usefulness of this feature,
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however, since we could print out the results anyway, because it is our
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application making the calls to the DLL. Where DLL forwarding is most useful
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is where an application or DLL we didn't write calls functions in the DLL.
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In this case we can capture the sequence of calls made, and the values passed
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around. This is an aid in reimplementing the DLL, since we can add code for a
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function, print the results, and then call the real DLL and compare. Only
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when our code is the same do we need to remove the function pointer and the
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call to the real DLL. A similar feature in wine is +relay debugging. Using a
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fowarding DLL allows more granular reporting of arguments, because you can
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write code to dump out the contents of types/structures rather than just
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their address in memory. A future version of specmaker may generate this
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code automatically for common Win32 types.
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See below for more information on setting up a forwarding DLL.
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Problems compiling a DLL containing generated code
|
||
|
--------------------------------------------------
|
||
|
|
||
|
Unless you are very lucky, you will need to do a small amount of work to
|
||
|
get a DLL generated with -c, -t or -f to compile. The reason for this is
|
||
|
that most DLLs will use custom types such as structs whose definition
|
||
|
is not known to the code in the DLL.
|
||
|
|
||
|
Heres an example prototype from crtdll:
|
||
|
|
||
|
double __cdecl _cabs(struct _complex arg0)
|
||
|
|
||
|
The definition for the _complex struct needs to be given. Since it is passed
|
||
|
by value, its size also needs to be correct in order to forward the call
|
||
|
correctly to a native DLL. In this case the structure is 8 bytes in size, which
|
||
|
means that the gcc compile flag -freg-struct-return must be given when
|
||
|
compiling the function in order to be compatable with the native DLL. (In
|
||
|
general this is not an issue, but you need to be aware of such issues if you
|
||
|
encounter problems with your forwarding DLL).
|
||
|
|
||
|
For third party (non C++) DLL's, the header(s) supplied with the DLL can
|
||
|
normally be added as an include to the generated DLL header. For other DLLs
|
||
|
I suggest creating a seperate header in the DLL directory and adding any
|
||
|
needed types to that. This allows you to rebuild the DLL at whim, for example
|
||
|
if a new version of specmaker brings increased functionality, then you
|
||
|
only have to overwrite the generated files and re-include the header to take
|
||
|
advantage of it.
|
||
|
|
||
|
Usually there isn't much work to do to get the DLL to compile if you have
|
||
|
headers. As an example, building a forwarded crtdll, which contains 520
|
||
|
functions, required 20 types to be defined before it compiled. Of these,
|
||
|
about half were structures, so about 35 lines of code were needed. The only
|
||
|
change to the generated code was one line in the header to include the type
|
||
|
definitions.
|
||
|
|
||
|
To save some typing in case you don't have headers for your DLL type, specmaker
|
||
|
will dump dummy declarations for unknown classes and types it encounters,
|
||
|
if you use the -v option. These can be piped directly into a fix-up header
|
||
|
file for use in compiling your DLL. For example, if specmaker encounters the
|
||
|
(C++ ) symbol:
|
||
|
|
||
|
??0foobar@@QAE@ABV0@@Z (Which is a constructor for a foobar object)
|
||
|
|
||
|
It will emit the following with -v set:
|
||
|
|
||
|
struct foobar { int _FIXME; };
|
||
|
|
||
|
(Classes are mapped to C structs when generating code).
|
||
|
|
||
|
The output should be piped through 'sort' and 'uniq' to remove multiple
|
||
|
declarations, e.g:
|
||
|
|
||
|
specmaker -d foo -c -I "inc/*.h" -v | grep FIXME | sort | uniq > fixup.h
|
||
|
|
||
|
By adding '#include "fixup.h"' to foobar_dll.h your compile errors will be
|
||
|
greatly reduced.
|
||
|
|
||
|
If specmaker encounters a type it doesnt know that is passed by value (as in
|
||
|
the _cabs example above), it also prints a FIXME message like:
|
||
|
|
||
|
/* FIXME: By value type: Assumed 'int' */ typedef int ldiv_t;
|
||
|
|
||
|
If the type is not an int, you will need to change the code and possibly
|
||
|
the .spec entry in order to forward correctly. Otherwise, include the typedef
|
||
|
in your fixup header to avoid compile errors.
|
||
|
|
||
|
|
||
|
Using a forwarding DLL
|
||
|
----------------------
|
||
|
|
||
|
To create and use a forwarding DLL to trace DLL calls, you need to first
|
||
|
create a DLL using the -f option as outlined above, and get it to compile.
|
||
|
In order to forward calls the following procedure can be used (for this
|
||
|
example we are going to build a forwarding msvcrt.dll for the purpose
|
||
|
of reimplementing it).
|
||
|
|
||
|
First we create the forwarding DLL. We will rename the real msvcrt.dll on our
|
||
|
system to ms_msvcrt.dll, and our msvcrt implementation will call it:
|
||
|
|
||
|
specmaker -d msvcrt -C -f ms_msvcrt -I "inc/*.h"
|
||
|
|
||
|
We then install this DLL into the Wine tree and add the types we need to
|
||
|
make it compile. Once the DLL compiles, we create a dummy ms_msvcrt DLL so
|
||
|
winebuild will resolve our forward calls to it (for the cases where specmaker
|
||
|
couldn't generate code and has placed an '@forward' line in the .spec file):
|
||
|
|
||
|
specmaker -d msvcrt -C -o ms_msvcrt
|
||
|
|
||
|
Install this DLL into the wine tree (since its a stub DLL, no changes are
|
||
|
needed to the code).
|
||
|
|
||
|
Now uncomment the line that specmaker inserted into msvcrt.spec:
|
||
|
|
||
|
#inport ms_msvcrt.dll
|
||
|
|
||
|
And recompile Wine.
|
||
|
|
||
|
Finally, we must tell Wine to only use the builtin msvcrt.dll and to only use
|
||
|
the native (Win32) ms_msvcrt.dll. Add the following two lines to ~/.wine/config
|
||
|
under the [DllOverrides] section:
|
||
|
|
||
|
;Use our implmentation of msvcrt
|
||
|
"msvcrt" = "builtin, so"
|
||
|
;Use only the Win32 ms_msvcrt
|
||
|
"ms_msvcrt" = "native"
|
||
|
|
||
|
At this point, when any call is made to msvcrt.dll, Our libmsvcrt.so recieves
|
||
|
the call. It then forwards or calls ms_msvcrt.dll, which is the native dll. We
|
||
|
recieve a return value and pass it back to our caller, having TRACEd the
|
||
|
arguments on the way.
|
||
|
|
||
|
At this point you are ready to start reimplementing the calls.
|
||
|
|
||
|
|
||
|
Final comments
|
||
|
--------------
|
||
|
|
||
|
If you have any suggestions for improving this tool, please let me know.
|
||
|
If anyone can help answer the FIXME questions in msmangle.c or can fill me in
|
||
|
on any aspect of the C++ mangling scheme, I would appreciate it. In particular
|
||
|
I want to know what _E and _G represent.
|
||
|
|
||
|
If you encounter a C++ symbol that doesn't demangle **AND** you have the
|
||
|
prototype for it, please send me the symbol as reported by specmaker and the
|
||
|
prototype. The more examples I have the easier it is to decypher the scheme,
|
||
|
and generating them myself is very slow.
|
||
|
|
||
|
Finally, although it is easy to generate a DLL, I _very strongly_ suggest that
|
||
|
you dont submit a generated DLL for inclusion into Wine unless you have
|
||
|
actually implemented a fairly reasonable portion of it. Even then, you should
|
||
|
only send the portions of the DLL you have implemented. Thousands of lines of
|
||
|
stub code don't help the project at all.
|
||
|
|
||
|
Please send questions and bug reports to jon_p_griffiths@yahoo.com.
|
||
|
|
||
|
|
||
|
References
|
||
|
----------
|
||
|
|
||
|
[1] See the Wine and Wine.conf man pages for details on how to tell Wine
|
||
|
whether to use native (Win32) or internal DLLs.
|
||
|
|