12 KiB
Binary Compatibility and wxWidgets
Purpose
This is a broad technote covering all aspects of binary compatibility with wxWidgets.
Releases
General overview of releases can be found in tn0012.txt, but for completeness the wxWidgets release version number is as follows:
2.6.2
Where
2 6 2
Major Minor Release
(I.E. Major.Minor.Release).
All versions with EVEN minor version component (e.g. 2.4.x, 2.6.x etc.)
are expected to be binary compatible (ODD minors are development versions
and the compatibility constraints don't apply to them). Note that by
preserving binary compatibility we mean BACKWARDS compatibility only,
meaning that applications built with old wxWidgets headers should continue
to work with new wxWidgets (shared/dynamic) libraries without the need to
rebuild. There is no requirement to preserve compatibility in the other
direction (i.e. make new headers compatible with old libraries) as this
would preclude any additions whatsoever to the stable branch. But see
also the section about wxABI_VERSION
.
What kind of changes are NOT binary compatible
If it's still up, the KDE guide is a good reference.
The changes that are NOT binary compatible:
- Adding a virtual function
- Changing the name of any function or variable
- Changing the signature of a virtual function (adding a parameter, even a default one)
- Changing the order of the virtual functions in a class ("switching" them, etc.)
- Changing access privileges of a function: some compilers (among which MSVC) use the function access specifier in its mangled name. Moreover, while changing a private function to public should be compatible (as the old symbol can't be referenced from outside the library anyhow), changing a virtual private function to public is NOT compatible because the old symbol is referenced by the virtual tables in the executable code and so an old program compiled with MSVC wouldn't start up with a new DLL even if it doesn't use the affected symbol at all!
- Adding a member variable
- Changing the order of non-static member variables
Changes which are compatible
- Adding a new class
- Adding a new non-virtual method to an existing class
- Adding a new constructor to an existing class
- Overriding the implementation of an existing virtual function (this is considered to be backwards binary compatible until we find a counter example; currently it's known to work with Apple gcc at least)
- Anything which doesn't result in ABI change at all, e.g. adding new macros, constants and, of course, private changes in the implementation
wxABI_VERSION
and "forward" binary compatibility
As mentioned we do not support "forward" binary compatibility, that is the ability to run applications compiled with new wxWidgets headers on systems with old wxWidgets libraries.
However, for the developers who want to ensure that their application works
with some fixed old wxWidgets version and doesn't (inadvertently) require
features added in later releases, we provide the macro wxABI_VERSION
which
can be defined to restrict the API exported by wxWidgets headers to that of
a fixed old release.
For this to work, all new symbols added to binary compatible releases must
be #if
'ed with wxABI_VERSION
.
The layout of wxABI_VERSION
is as follows:
20602
where
2 06 02
Major Minor Release
I.E. it corresponds to the wxWidgets release in (1).
An example of using wxABI_VERSION
is as follows for symbols
only in a 2.6.2 release:
```cpp
#if wxABI_VERSION >= 20602 /* 2.6.2+ only */
bool Load(const wxURI& location, const wxURI& proxy);
wxFileOffset GetDownloadProgress();
wxFileOffset GetDownloadTotal();
bool ShowPlayerControls(
wxMediaCtrlPlayerControls flags =
wxMEDIACTRLPLAYERCONTROLS_DEFAULT);
//helpers for the wxPython people
bool LoadURI(const wxString& fileName)
{ return Load(wxURI(fileName)); }
bool LoadURIWithProxy(const wxString& fileName, const wxString& proxy)
{ return Load(wxURI(fileName), wxURI(proxy)); }
#endif
```
Workarounds for adding virtual functions
Originally the idea for adding virtual functions to binary compatible releases was to pad out some empty "reserved" functions and then rename those later when someone needed to add a virtual function.
However, after there was some actual testing of the idea a lot of controversy erupted. Eventually we decided against the idea, and instead devised a new method for doing so called wxShadowObject.
wxShadowObject is a class derived from wxObject that provides a means of adding functions and/or member variables to a class internally to wxWidgets. It does so by storing these in a hash map inside of it, looking it up when the function etc. is called. wxShadowObject is generally stored inside a reserved member variable.
wxShadowObject resides in include/wx/clntdata.h.
To use wxShadowObject, you first call AddMethod or AddField with the first parameter being the name of the field and/or method you want, and the second parameter being the value of the field and/or method.
In the case of fields this is a void*, and in the case of method is a wxShadowObjectMethod which is a typedef:
typedef int (*wxShadowObjectMethod)(void*, void*);
After you add a field, you can set it via SetField with the same parameters as AddField, the second parameter being the value to set the field to. You can get the field after you call AddField via GetField, with the parameters as the other two field functions, only in the case the second parameter is the fallback value for the field in the case of it not being found in the hash map.
You can call a method after you add it via InvokeMethod, which returns a bool indicating whether or not the method was found in the hash map, and has 4 parameters. The first parameter is the name of the method you wish to call, the second is the first parameter passed to the wxShadowObjectMethod, the third is the second parameter passed to that wxShadowObjectMethod, and the fourth is the return value of the wxShadowObjectMethod.
version-script.in
For ld/libtool we use sun-style version scripts. Basically
anything which fits the conditions of being #if
'ed via wxABI_VERSION
needs to go here also.
See 'info ld scripts version' on a GNU system, it's online here: http://www.gnu.org/software/binutils/manual/ld-2.9.1/html_node/ld_25.html
Or see chapter 5 of the 'Linker and Libraries Guide' for Solaris, available online here: http://docsun.cites.uiuc.edu/sun_docs/C/solaris_9/SUNWdev/LLM/p1.html
The file has the layout as follows:
@WX_VERSION_TAG@.X
Where X is the current Release as mentioned earlier, i.e. 2. This is following by an opening bracket "{", followed by "global:", followed by patterns matching added symbols, then followed by "}", and then the file is either followed by earlier Releases or ended by a @WX_VERSION_TAG@ block without the period or Release.
The patterns used to specify added symbols are globbing patters and can contain wildcards such as '*'.
For example for a new class member such as:
wxFont wxGenericListCtrl::GetItemFont( long item ) const;
the mangled symbol might be:
_ZNK17wxGenericListCtrl11GetItemFontEl
so a line like this could be added to version-script.in:
\*wxGenericListCtrl*GetItemFont*;
Allow for the fact that the name mangling is going to vary from compiler to complier.
When adding a class you can match all the symbols it adds with a single pattern, so long as that pattern is not likely to also match other symbols. For example for wxLogBuffer a line like this:
\*wxLogBuffer*;
Checking the version information in libraries and programs
On Sun there is a tool for this, see pvs(1). On GNU you can use objdump, below are some examples.
To see what versions of each library a program (or library) depends on:
$ objdump -p widgets | sed -ne '/Version References/,/^$/p'
Version References:
required from libgcc_s.so.1:
0x0b792650 0x00 10 GCC_3.0
required from libwx_based-2.6.so.0:
0x0cca2546 0x00 07 WXD_2.6
required from libstdc++.so.6:
0x056bafd3 0x00 09 CXXABI_1.3
0x08922974 0x00 06 GLIBCXX_3.4
required from libwx_gtk2d_core-2.6.so.0:
0x0a2545d2 0x00 08 WXD_2.6.2
0x0cca2546 0x00 05 WXD_2.6
required from libc.so.6:
0x09691a75 0x00 04 GLIBC_2.2.5
To see what WXD_2.6.2 symbols a program uses:
$ objdump -T widgets | grep 'WXD_2\.6\.2'
0000000000000000 g DO *ABS* 0000000000000000 WXD_2.6.2 WXD_2.6.2
00000000004126d8 DF *UND* 0000000000000177 WXD_2.6.2 _ZN19wxTopLevelWindowGTK20RequestUserAttentionEi
To see what WXD_2.6.2 symbols a library defines:
$ objdump -T libwx_based-2.6.so | grep 'WXD_2\.6\.2' | grep -v 'UND\|ABS'
0000000000259a10 w DO .data 0000000000000018 WXD_2.6.2 _ZTI19wxMessageOutputBest
00000000002599e0 w DO .data 0000000000000028 WXD_2.6.2 _ZTV19wxMessageOutputBest
000000000010a98e w DF .text 000000000000003e WXD_2.6.2 _ZN19wxMessageOutputBestD0Ev
0000000000114efb w DO .rodata 000000000000000e WXD_2.6.2 _ZTS11wxLogBuffer
0000000000255590 w DO .data 0000000000000018 WXD_2.6.2 _ZTI11wxLogBuffer
000000000011b550 w DO .rodata 0000000000000016 WXD_2.6.2 _ZTS19wxMessageOutputBest
00000000000bfcc8 g DF .text 00000000000000dd WXD_2.6.2 _ZN11wxLogBuffer5DoLogEmPKcl
000000000010a3a6 g DF .text 0000000000000153 WXD_2.6.2 _ZN19wxMessageOutputBest6PrintfEPKcz
00000000000c0b22 w DF .text 000000000000004b WXD_2.6.2 _ZN11wxLogBufferD0Ev
00000000000bfc3e g DF .text 0000000000000089 WXD_2.6.2 _ZN11wxLogBuffer5FlushEv
00000000000c0ad6 w DF .text 000000000000004b WXD_2.6.2 _ZN11wxLogBufferD1Ev
00000000000b1130 w DF .text 0000000000000036 WXD_2.6.2 _ZN11wxLogBufferC1Ev
00000000000c095c w DF .text 0000000000000029 WXD_2.6.2 _ZN19wxMessageOutputBestC1Ev
00000000000c08e8 w DF .text 000000000000003e WXD_2.6.2 _ZN19wxMessageOutputBestD1Ev
00000000002554c0 w DO .data 0000000000000038 WXD_2.6.2 _ZTV11wxLogBuffer
00000000000bfda6 g DF .text 0000000000000036 WXD_2.6.2 _ZN11wxLogBuffer11DoLogStringEPKcl
00000000000abe10 g DF .text 0000000000000088 WXD_2.6.2 _ZN14wxZipFSHandler7CleanupEv
Testing binary compatibility between releases
An easy way of testing binary compatibility is just to build wxWidgets in dll/dynamic library mode and then switch out the current library in question with an earlier stable version of the library, then running the application in question again. If it runs OK then there is usually binary compatibility between those releases.
You can also break into your debugger or whatever program you want to use and check the memory layout of the class. If it is the same then it is binary compatible. (In GDB the command x/d will show addresses as pointers to functions if possible so you can see if the order of the functions in vtbl doesn't change.)
Another way to check for binary compatibility is to build wxWidgets in shared mode and use the 'abicheck.sh --generate' script before doing your changes to generate the current ABI (if the 'expected_abi' file is not already in the repo). Then rebuild wxWidgets with your changes and use 'abicheck.sh' to compare the resulting ABI with the expected one. Note that the abicheck.sh script is in the "lib" folder.