Hot answers tagged dwarf
As the DWARF spec says in section 6.4: [...] The call frame is identified by an address on the stack. We refer to this address as the Canonical Frame Address or CFA. Typically, the CFA is defined to be the value of the stack pointer at the call site in the previous frame (which may be different from its value on entry to the current frame). ...
On Mac OS X there was a decision to have the linker (ld) not process all of the debug information when you link your program. The debug information is often 10x the size of the program executable so having the linker process all of the debug info and include it in the executable binary was a serious detriment to link times. For iterative development - ...
I would suggest using gdb as the simplest approach. You can even do it as a one-liner, like: gdb -batch -ex 'file /bin/ls' -ex 'disassemble main'
I used the following arithmetic to figure it out: slide + stack address - load address = symbol address and stack address is the hex value I get from my stack dump crash report (not a .crash file, just the stack dump). and slide is the vmaddr of the LC_SEGMENT cmd when running otool -arch armv7 -l APP_BINARY_PATH. Mine usually ends up being 0x00001000. ...
There's a new kid on the block - pyelftools - a pure Python library for parsing the ELF and DWARF formats. Give it a try. It aims to be feature-complete and is currently in active development, so any problems should be handled quickly and enthusiastically :-)
Here is what I will do. Why reinvent the wheel! Download linux commands that will be needing on windows from here. on the bin directory there should be: readelf.exe Note we will not need Cygwin or any program so deploying will be simple! Once we have that file execute in cmd: // cd "path where readelf.exe is" readelf.exe -s a.out and this is the list ...
As it happens, the module that could not debug was mostly built from sources except for one little 'external' object file someextcode.o that was provided by a 3rd party. In investigating the problem it was found that the someextcode.c was compiled with the -g3 flag which, apparently, places DWARF version of 4 in the compilation unit header. Changing that to ...
In Linux environment? If you have GCC installed, you should have readelf executable. So you can try this readelf --debug-dump=info binary_name | grep -A 2 'Compilation Unit @'
If cleaning up the mpic++ object files doesn't solve it you can tell g++ not to emit DWARF3 info with -gdwarf-2 -gstrict-dwarf
An executable's (mach-o file) UUID is created by the linker ld and is stored in a load command named LC_UUID. You can see all load commands of a mach-o file using otool: otool -l path_to_executable > ... > Load command 8 > cmd LC_UUID > cmdsize 24 > uuid 3AB82BF6-8F53-39A0-BE2D-D5AEA84D8BA6 > ... Any process can access its ...
The concept of "ELF debug info" doesn't really exist: the ELF specification leaves the content of the .debug section deliberately unspecified. Common debug formats are STAB and DWARF. A library to read DWARF is libdwarf.
The problem is that your version of GDB doesn't support the DWARF version used in one of your binaries. The solution: Update GDB or compile your files using another debug format (DWARF2 works on GDB 6). I have recently had this problem with freeBSD and nasm, nasm compiling binaries with dwarf3 and the gdb that ships with freeBSD 9.1 doesn't accept it. I ...
First of all check if the dSYM is really the correct one for that app: dwarfdump --uuid kidsapp.app/kidsapp dwarfdump --uuid kidsapp.app.dSYM Both should return the same result. Next check if the dSYM has any valid content dwarfdump --all kidsapp.app.dSYM This should give at least some info, other than not found. I guess that the dSYM is corrupt. In ...
You might be interested in the DWARF library from pydevtools: >>> from bintools.dwarf import DWARF >>> dwarf = DWARF('test/test') >>> dwarf.get_loc_by_addr(0x8048475) ('/home/emilmont/Workspace/dbg/test/main.c', 36, 0)
Firstly, why is so much DWARF debug info included in the Release build of a C executable? Being able to debug optimized code is incredibly useful. Cases in which bugs are only visible in optimized builds are not rare. If you're hand writing assembly you're unlikely to care about DWARF information though, so I'd suggest building your comparison code ...
You might be interested in the DWARF library from pydevtools: >>> from devtools.dwarf import DWARF >>> dwarf = DWARF('test/test') >>> dwarf.get_loc_by_addr(0x8048475) ('/home/emilmont/Workspace/dbg/test/main.c', 36, 0) >>> print dwarf .debug_info COMPILE_UNIT<header overall offset = 0> <0><11> ...
I think you should look at the AST Library since the AST (Abstract Syntax Tree) is used to represent parsed information. If you want to learn by example, the Clang Static Analyzer might be of interest for you, because it parses the C source and performs static code checks to find bugs.
You might find useful informations here: David A's DWARF Page SO question
Because you are using gcc -c -g -m32 test.c -o test.o. Although it is a fastcall function, GCC still needs to generate code to save values from registers to the stack frame at the beginning of the function. Without that, any debugger or gdb cannot debug the program or they will say the argument is being optimized and not shown. It makes debugging impossible. ...
The problem stems from the fact that you are using terribly outdated GCC, while your Qt binaries are most likely built with bleeding-edge GCC (or the one close to it). For instance, as the error message shows, DWARF is outdated in case of your current GCC and is incompatible with the one used by your current Qt. Furthermore, even if it wouldn't, you'd still ...
Download the Cygwin setup.exe and use it to install the binutils package.
Please check pyelftools - a new pure Python library meant to do this.
The specification for DWARF-2 & DWARF-3 is here: http://dwarfstd.org/dwarf-2.0.0.pdf http://dwarfstd.org/Dwarf3.pdf There is a decent library for reading DWARF files here: http://reality.sgiweb.org/davea/dwarf.html You can either get and use that library to read your DWARF files (it reads DWARF-2 and DWARF-3) or you can take a look at the source ...
You should give Construct a try. It is very useful to parse binary data into python objects. There is even an example for the ELF32 file format.
It seems you need to link the libelf library too (the dwarf library uses it).
It's a symbolic register name. See the xxx_map_dwarf_register methods in WineHQ's source for: i386 x86_64 sparc arm For example, DW_OP_breg4 is ESP on i386. Also see the following if you haven't done so already. http://source.winehq.org/source/dlls/dbghelp/dwarf.c http://www.dwarfstd.org/doc/040408.1.html
Optimized debug info is still a pretty new area for llvm. It's under active development, but a lot of it depends on what you're looking for. Precise variable tracking isn't really there as it undergoes transformations - variable information is occasionally lost. The SROA pass is particularly bad about it at the moment. That said, if you're looking for line ...
This happens even if you compile a minimal C program as follows: Even this minimal program will statically link parts of libc (namely, crt1.o, crtbegin.o, etc.). You should verify that the compilation units that have version 4 are really coming from your program, and not from a library (just look at their DW_AT_name and DW_AT_comp_dir). My gcc-4.8: ...
Use the -fdebug-prefix-map=old_path=new_path option to GCC. As far as I can find, LLVM/Clang does not provide an equivalent option.
This is an answer to an old question, but your problem matched mine, but none of the solutions worked. Here is what worked for me. Change CFLAGS -g to "-g -gstabs". objdump was not recognizing the dwarf style debug information. -gstabs changes this format to one that works with objdump -g and objdump -S and my debugger. Hope it helps. NOTE: For me, ...
Only top voted, non community-wiki answers of a minimum length are eligible