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diff --git a/xorg-server/hw/xfree86/doc/devel/DebuggingHints b/xorg-server/hw/xfree86/doc/devel/DebuggingHints new file mode 100644 index 000000000..300fe4813 --- /dev/null +++ b/xorg-server/hw/xfree86/doc/devel/DebuggingHints @@ -0,0 +1,192 @@ + + Xserver Debugging + ================= + +This file is intended to collect helpful hints on Xserver debugging. +I merely outline my experiences here. Somebody else might have better +methods on doing it. This person is therefore invited to share this +experience with the rest of the world by adding it here. + +Paul Flinders has made some patches to gdb to add support for loadable +modules. This version of gdb is currently available as binary for +Linux/x86 on Paul's web site: + + www.dawa.demon.co.uk/xfree-gdb + +This web-site also contains the patches to gdb 4.18 so you may port it +to other platforms. + +It loads the module symbols and supports all gdb features like +breakpointing, disassembling and single stepping. It also shows the +exact location of a signal 11. Paul has fixed the code so that all of +this is working even if using modules compiled without -g. You can +find his latest version on his web site. + +If no module aware gdb is available the following hints might help: + +1. Use remote login. This can be done thru a network connection or + simply by connecting a serial console. This enables you to watch + the Xservers output while running set breakpoints with gdb etc. + Don't even try to run the Xserver from a system console. Whenever + something happens gdb waits for input. However the Xserver has + locked the system console including the keyboard, therefore you'll + never be able to send any input to gdb. Even if your process + doesn't crash or you haven't set any breakpoints a vt switch can be + hazardous: When doing vt switching a signal is sent; unless you did + + gdb> handle SIGUSR1 nostop + + gdb waits for you to continue the program which cannot happen as + you don't have access to gdb's console. + +2. You can compile any source file with debugging symbols to obtain + more information about where an error occurred. Simply go to the + directory which holds the corresponding object file and do: + + # rm <file>.o + # xc/config/util/makeg.sh <file>.o + + After relinking the server or module gdb is able to obtain the + necessary debugging information and will show the exact line in the + source where the error ccurred. See also: + xc/config/util/makeg.man. + +3. In some cases it might be useful to have the assembler output of a + compiled source file. This can be obtained by doing: + + # make <file>.s + + or + + # xc/config/util/makeg.sh <file>.s + + Make will use exactly the same rules it uses for building *.o files. + +4. In some cases it might be useful to set breakpoints in modules. If + no module aware gdb is available you should add a call to one of + the three dummy breakpoint functions + + xf86Break1(), xf86Break2() and xf86Break3() + + to the source file and recompile the module. You now just have to + set a breakpoint onto the appropriate dummy functions. These + functions are located in the core part of the server and therefore + will be available any time. + +5. Without module support gdb is not able to print the function where + an error occurred in a module. + + If you get a line like: + + (gdb) bt + #0 0x823b4f5 in ?? () + .... + + You may obtain the function the address belongs to by calling + LoaderPrintSymbol(): + + (gdb) call LoaderPrintSymbol(0x823b4f5) + + The symbol returned might not always be the name of the function + which contains the address. In case of static functions the symbol + is not known to the loader. However LoaderPrintSymbol() will print + the nearest known function and the offset from its start. You may + easily find the exact location of the address if you do: + + # objdump --disassemble <file>.o + + <file>.o is the name of the object file containing the symbol printed. + +6. Locating static symbols in modules is simpler if the module is a + single object file instead of a library. Such a object file can + easily be build from a library: # mkdir tmp # cd tmp; ar x + module-path/<libname>.a # ld -r *.o -o module-path/<name>.o + + When calling LoaderPrintSymbol() the closes public symbol will be + printed together with the offset from the symbol's address. If a + static symbol comes before the first public symbol in a module The + following trick may help: + + create a file 1-<name>.c in tmp/ + containing: + void Dummy-<name>() {} + + Compile it: + + # gcc -c 1-<name>.c + + and do the link step above. + + This way Dummy-<name>() will be the first public function in the + module. All addresses in static function can now be printed + relatively to this address if no other public function comes before + this static one. + +7. In some situations it is quite helpful to add debugging symbols to + the binary. This can be done per object file. Simply remove the + object file and do + + # makeg + + When looking for a bug in a module these debugging infos can be + very helpful: Calling LoaderPrintSymbol() as described above will + return a function and an offset giving the exact location of the + address with respect to this function entry point. When + disassembling an object file with debugging symbols: # objdump -d + -l <file>.o one will receive a disassembled output containing line + number information. Thus one can locate the exact line of code + where the error occurred. + +8. To quickly trace the value of a variable declared in a module three + dummy variables have been added to the core part: + + CARD32 xf86DummyVar1; + CARD32 xf86DummyVar2; + CARD32 xf86DummyVar3; + + The variable can be assigned to one of them. One can then use gdb + to return the value of this variable: + + gdb> p /x xf86DummyVar1 + +9. Sometimes it might be useful to check how the preprocessor replaced + symbols. One can obtain a preprocessed version of the source file + by doing: + + make <filename>.i + + This will generate a preprocessed source in <filename>.i. + +10. xfree() can catch if one tries to free a memory range twice. You + will get the message: + + Xalloc error: range already freed in Xrealloc() :-( + + To find the location from which xfree() was called one can + breakpoint on XfreeTrap(). The backtrace should show the origin of the + call this call. + +11. To access mapped physical memory the following functions might be + useful. + + These may be used to access physical memory that was mapped using + the flags VIDMEM_FRAMEBUFFER or VIDMEM_MMIO32: + + CARD8 xf86PeekFb8(CARD8 *p); + CARD16 xf86PeekFb16(CARD16 *p); + CARD32 xf86PeekFb32(CARD32 *p); + void xf86PokeFb8(CARD8 *p, CARD8 v); + void xf86PokeFb16(CARD16 *p, CARD16 v); + void xf86PokeFb32(CARD16 *p, CARD32 v); + + Physical memory which was mapped by setting VIDMEM_MMIO should be + accessed using the following. Here the base address to which the + memory is mapped and the offset are required separately. + + CARD8 xf86PeekMmio8(pointer Base, unsigned long Offset); + CARD16 xf86PeekMmio16(pointer Base, unsigned long Offset); + CARD32 xf86PeekMmio32(pointer Base, unsigned long Offset); + void xf86PokeMmio8(pointer Base, unsigned long Offset, CARD8 v); + void xf86PokeMmio16(pointer Base, unsigned long Offset, CARD16 v); + void xf86PokeMmio32(pointer Base, unsigned long Offset, CARD32 v); + |