Linux GCC FAQ 22nd May 1994

Click on a question number or underlined text to go to the relevant section

0) Where can I get the latest version of this FAQ ? 1) How do I tell what version of GCC I am using ? 2) Where is the latest distribution of GCC, as, ld, ar, etc.. ? 3) Where can I find the newest shared libraries libc.so and libm.so ? 4) What other shared libraries are available for Linux ? 5) How do I build a shared DLL library for Linux ? 6) Why do I get the message "PLT__oct__FUii" when I execute a certain binary ? 7) How do I build a cross compiler on platform XXX to produce code for Linux ? 8) What symbols are automatically defined by Linux's GCC ? 9) How do I get over BSD'isms (especially signals, sigvec etc..) when compiling code ? 10) Where are SIGBUS, SIGEMT, SIGIOT, SIGTRAP, SIGSYS etc ? 11) What is libhard and libsoft ? 12) What does the message "can't load library: /lib/libxxx.so, Incompatible version" mean ? 13) Why are my binaries so huge and how do I reduce them ? 14) What does the -N flag do, and when should I use it ? 15) How do I get debugging information into a program ? 16) What debuggers are available for Linux ? 17) How do I debug a daemon program ? 18) What is profiling and how do I profile a program ? 19) Is there a way to tell if a binary is linked statically or to a shared library ? 20) Does Linux have support for LD_LIBRARY_PATH ? 21) My program wants /lib/cpp ! Where can I get it from ? 22) Where are <float.h>, <limits.h>, <varargs.h>, <stdarg.h> and <stddef.h> ? 23) My program wants to include <linux/foo.h> but cannot find it, where is it ? 24) Do we have the function foo() in our libraries ? 25) How do I port program XXX to Linux ? 26) I think I have found a bug in gcc/library foo, what do I do now ? 27) Why are shared libraries so large in comparison to their static counterparts ? 28) What are .sa file I see in /usr/lib ? 29) Where can I get Objective C for Linux ? 30) What does the message "Internal compiler error: cc1 got fatal signal 11,4" mean ? 31) What is a libc-lite ? 32) Does Linux libraries have SHADOW Password support, and how do I switch it on/off ? 33) Can't find math.h routines ! My program compiles but cannot find log(), sin(), etc.., HELP !! 34) Is there a manual for GCC? If so, where do I get it, and how do I print it out ? 35) I get the message "Undefined symbol _bsd_ioctl". Where is this anyhow ? 36) If I upgrade versions, can I get rid of the old stuff from /usr/lib/gcc-lib/i[34]86-linux/<old-version> ? 37) [HELP] where is libipc.a ? Needed for dosemu 0.49.. 38) XXX won't compile: _daemon undefined, help !! 39) [HELP] ar and libraries. Linking fails although symbol appears in library. 40) HELP! newbie gets warning message "libc.so.4: incompat. minor ver no." 41) Where can I find `lint' to check my c programs before compilation ? 42) My program needs sgtty.h where is it ? 43) How do I stop or start core files being produced SIGSEGV's ? 44) What does the message "can't load dynamic linker `/lib/ld.so'" mean ? 45) What is the difference between -O2 and -O6 optimizations ? 46) How can I check an unknown binary to see if it is a trojan horse ? 47) Where are the sources to the C library - how do I rebuild it ? 48) Where are the definitions of FD_* stuff ? 49) When linking with option -g I get undefined ___fpu_control and ___setfpucw ? 50) Where can I get the tools to Internationalize my library/application ? 51) The DLL tool `mkimage' fails to find libgcc. Help!!! 52) How do I get rid of "__NEEDS_SHRLIB_libc_4 multiply defined" messages ? 53) What is this QMAGIC thing everyone is talking about ? 54) How do I generate a QMAGIC executable/library ? 55) Is it possible to turn the "warning using incompatable library version xxx" messages off ? 56) Is GNU's glibc 1.06 texinfo manual pages relevant to Linux's libc? 57) Can I sell my application if it was compiled within linux ?? 58) Why do I get an "Assertion failure" message when rebuilding a DLL ?? ============================================================================== ============================================================================== 0) Where can I get the latest version of this FAQ ? Ans: The latest versions are posted to comp.os.linux.announce periodically, and archived in at most popular Linux sites, e.g. sunsite.unc.edu:/pub/Linux/docs/faqs rtfm.mit.edu:pub/usenet/news.answers -------------------------------------------------------------------------------

1) How do I tell what version of GCC I am using ? Ans: Execute the command gcc -v to find out what version you are using. At the time of writing the above command produces on my machine Reading specs from /usr/lib/gcc-lib/i386-linux/2.5.8/specs gcc version 2.5.8 You would be well advised to upgrade to a version similar to this or above. P.S. If you get the output Reading specs from /usr/lib/gcc-lib/i486-linux/2.5.8/specs gcc version 2.5.8 you are running a gcc compiled for a 486. -------------------------------------------------------------------------------

2) Where is the latest distribution of GCC, as, ld, ar, etc.. ? Ans: The Official place for GCC distributions is tsx-11.mit.edu in /pub/linux/packages/GCC. All others sites mirror this. The latest versions of all GCC stuff will be found here. At the time of writing, the latest GCC is version for Linux is 2.5.8 and available from tsx-11.mit.edu:/pub/linux/packages/GCC/gcc-2.5.8-p1.tar.gz However this does not mean that this is the latest available version of GCC from the GNU foundation. This is just the latest *distribution*. The Linux GCC maintainer(s) have made it easy for you to compile the latest version available yourself. The configure script with GCC sources should set it all up for you. You will also need the latest include (header) files if you wish to compile stuff. At the time of writing the latest includes can be obtained from tsx-11.mit.edu:/pub/linux/packages/GCC/inc-4.5.26.tar.gz The latest `as', `ld', `ar' etc may be found in the package tsx-11.mit.edu in /pub/linux/packages/GCC/linux-binutils-1.0.tar.gz -------------------------------------------------------------------------------

3) Where can I find the newest shared libraries libc.so and libm.so ? Ans: See question (4) below. You need the file image*.tar.gz. Only 486 images are provided (they work also on 386's - but the image size is slightly larger). You will need to recompile the shared libraries if you want 386 libaries. See question (47) on where to obtain the source code to the linux C library -------------------------------------------------------------------------------

4) What other shared libraries are available for Linux ? Ans: Ok here is a list I have been compiling. Any additions/changes graciously received. The locations given below were where they were last seen (or reportedly seen). They may have been moved by archive maintainers. P.S. For a more obvious description of the libraries below, their maintainers and their registered start/end address please read the `doc/table_description' file in the tools-x.y.tar.z package. See the following question (5) on where to obtain this from. Here are the locations of currently registered DLL libraries for Linux. ====================================================================== libc.so tsx-11.mit.edu:/pub/linux/packages/GCC/image-4.5.26.tar.gz libm.so included in above tar.gz file. libX11.so tsx-11.mit.edu:pub/linux/packages/X11/XFree86-2.1/XF86-2.1-lib.tar.gz libXt.so included in above tar.gz file. libXaw.so included in above tar.gz file. librl.so sunsite.unc.edu:/pub/Linux/libs/librl-1.2.tar.gz libgr.so sunsite.unc.edu:/pub/Linux/libs/graphics/libgr-1.3.tar.gz libf2c.so sunsite.unc.edu:/pub/Linux/devel/fortran/libf2c-0.9.2.tar.gz libF77.so use libf2c.so shown above instead. libI77.so use libf2c.so shown above instead. libXpm.so sunsite.unc.edu:/pub/Linux/libs/X/libXpm-3.4a.tar.gz libnsl.so ftp.lysator.liu.se:/pub/NYS/nys-0.xx.tar.gz (frequent updates) libolgx.so sunsite.unc.edu:/pub/Linux/libs/xview3L5.1.tar.gz libxview.so included in above tar.gz file. libsspkg.so included in above tar.gz file. libUIT.so included in above tar.gz file. libPEX.so tsx-11.mit.edu:pub/linux/packages/X11/XFree86-2.1/XF86-2.1-pex.tar.gz libtcl.so sunsite.unc.edu:/pub/Linux/devel/tcl/* libtk.so various related tcl/tk stuff included in above tar.gz files. libWc.so Unknown libXp.so Unknown libIV.so sunsite.unc.edu:/pub/Linux/X11/devel/iv-3.1l.2.tar.gz libUnidraw.so included in above .tgz files. libXm.so The Motif library is *not* free. See note below. libsrgp.so sunsite.unc.edu:/pub/Linux/X11/devel/suit.tpz libsuit.so included in above tpz file. (reported not shared) libOI.so tsx-11.mit.edu:/pub/linux/packages/OI/oi40.tar libOIrg.so included in above tar file. libld.so tsx-11.mit.edu:/pub/linux/packages/GCC/ld.so-1.4.3.tar.gz (required for libc 4.4.4 and above.) libarma.so ftp.atnf.csiro.au:/pub/karma libkarmaX11.so see above site libkarmaXt.so see above site libkarmagraphics.so see above site libkarmawidgets.so see above site libkarmaxview.so see above site libwxwin.so sunsite.unc.edu:/pub/Linux/X11/devel/wxWin_linux.tgz libandrew.so sunsite.unc.edu:/pub/Linux/X11/andrew/andrew61.prog.tar.gz libUil.so Commercial library. libBLT.so sunsite.unc.edu:/pub/Linux/devel/tcl/blt1.6-bin.tar.gz libvga.so sunsite.unc.edu:/pub/Linux/libs/graphics/svgalib111.tgz libitcl.so sunsite.unc.edu:/pub/Linux/devel/tcl/itcl1.3-bin.tar.z ------------ Note 1:- Drop in DLL libraries for Xaw to get a 3d effect (libXaw3d-0.6) and a Mac(TM) like scroll bar on Xaw clients are available respectively at sunsite.unc.edu:/pub/Linux/libs/Xaw3d-0.6B.3.1.1.bin.tar.gz and sunsite.unc.edu:/pub/Linux/libs/libXaw.Scrollbar.taz Note 2:- For motif libs you have to pay bucks !! Read an extract that follows... ------------ Metro Link, Inc. is pleased to announce the availability of OSF/Motif 1.2.2 for Linux at $199 for a complete runtime and development system. Requirements: Linux 0.99pl4 or greater (currently 0.99pl12 O.K.) XFree86 1.2 or greater (1.3 O.K.) libc 4.3.3 or greater (libc 4.4 is O.K.) What is included: Runtime: 1) Motif Window Manager (mwm) 2) Shared motif library (libXm.so.1.2.2) 3) Motif demos both from OSF and from the net Development: 2) Static Mrm and Uil libraries 3) UIL compiler 4) Motif header files 5) Manual pages for Motif function calls 6) Imakefile support 7) Source to OSF/Motif demos And your choice of any one of the X-window books published by O'Reilly & Associates, Inc. You can order OSF/Motif 1.2.2 for Linux by calling Metro Link,Inc. at (305) 970-7353 (voice) or (305) 970-7351 (fax) or by mailing us at sales@metrolink.com. ============================================================================== Metro Link Incorporated. 2213 W. McNab Rd. Pompano Beach, Florida 33069 X11.5 and OSF/Motif for QNX, SVR3, SVR4.[012], SCO, Linux, UnixWare, LynxOS, AT&T, Venix, ISC, Solaris, Pyramid, SunOS WATCH your: Word Action Thought Character Heart ============================================================================== -------------------------------------------------------------------------------

5) How do I build a shared DLL library for Linux ? Ans: You need to get the file tsx-11.mit.edu:/pub/linux/packages/GCC/src/tools-2.11.tar.gz from tsx-11.mit.edu, and install it. Read the README.tr in the doc subdirectory thoroughly - a lot of effort has been put into this to make it readable and possible for everyone to be able to build a shared DLL. If you find the README.tr more up to date than the README.ps, you will have to recreate it if you want a pretty Postscript version, but you *must* have groff installed. A `make README.ps' in the doc subdirectory should suffice. ** Note: the version numbers may have changed. -------------------------------------------------------------------------------

6) Why do I get the message "PLT__oct__FUii" when I execute a certain binary ? Ans: More likely than not you have a old version of the libraries, libc.so and/or you compiled a program using a incorrect version of `ld'. The solution is to get the new version of binutils package from tsx-11.mit.edu in /pub/linux/packages/GCC/binutils-1.9l.3-as-2.2l.tar.gz -------------------------------------------------------------------------------

7) How do I build a cross compiler on platform XXX to produce code for Linux ? Ans: Assuming you have obtained the source code to gcc, usually you can just follow the instructions given in the INSTALL file for GCC. A `configure --target=i386-linux-linux --host=XXX' on platform XXX followed by a `make' should do the trick. Note that you will need the linux includes, the kernel includes, and also to build cross assembler, and cross linker from the sources in /pub/linux/packages/GCC/src at tsx-11.mit.edu Here is an example of building a cross compiler on a Sparc (Sun) to produce code for a linux machine. This is the easy way, using linux libraries compiled by HLU that you already are using on your linux machine. For some of this I STRONGLY advise you to get GNU's make (gmake) to use for some of the compilations (binutils and gas will fail using the included Makefiles.linux with Sun's make) 7.1) Lets assume you already have a working gcc version 2.4.5 on the Sun in /usr/local/bin with all standard install paths - i.e the compilers are in /usr/local/lib/gcc-lib. First make the linux specific directories (you may need to make the intermediate directories too) up to % mkdir -p /usr/local/lib/gcc-lib/i386-linux-linux/bin % mkdir -p /usr/local/lib/gcc-lib/i386-linux-linux/2.4.5/include % mkdir /usr/local/lib/gcc-lib/i386-linux-linux/include 7.2) Start by setting some environment variables so you don't have to type long pathnames. Set this in your .login or .cshrc also as you will need to use l-ar, l-ranlib for cross compiling DLL's etc.. For the moment you can do the following In csh: % setenv LBINS /usr/local/lib/gcc-lib/i386-linux-linux/bin/ In sh: % LBINS=/usr/local/lib/gcc-lib/i386-linux-linux/bin/ % export LBINS Put *ALL* linux specific header file with all the contents of the subdirectories linux, asm, gnu, sys etc.. in ${LBINS}../include Make SURE of this. See questions (2) and (23) on where to get these from. You will have to do this each time a new kernel is released. On my linux machine sitting next to my sun I can say % rcp -r linux_machine:/usr/include ${LBINS}../ Otherwise you will need to get the includes and kernel sources, see questions (2), to achieve this. Also you will want the gnu specific files like limits.h, varargs.h, stdargs.h etc... Again from my linux machine I can say % rcp -r \ linux_machine:/usr/lib/gcc-lib/i386-linux/2.4.5/include \ ${LBINS}../2.4.5 You may have to change the i386 or 2.4.5 depending on your machine and version of gcc. 7.3) Now you have to extract and compile the cross assembler and linker: Get the following files tsx-11.mit.edu:/pub/linux/packages/GCC/src/binutils-1.9l.3.tar.gz tsx-11.mit.edu:/pub/linux/packages/GCC/src/gas-1.38.1l.2.tar.gz and extract them somewhere. 7.3.1) In the binutils dir binutils-1.9l.3: Edit Makefile.linux and change the line that has the bindir definition to have bindir=${LBINS} and the appropriate block for your machine ("sun4" in this case) line to HOST_ROOT=${LBINS}.. For 0.99pl12 (and above probably) you will have to copy a.out.h and page.h to a directory and include it in the MISCFLAGS. So in the current binutils dir, do this % mkdir linux % cp ${LBINS}../include/linux/a.out.h linux % cp ${LBINS}../include/linux/page.h linux and then edit the Makefile.linux and add -I. to the appropriate MISCFLAGS line. Then do % make -f Makefile.linux archpfx= install To be able to do l-ar, l-ranlib for the linux ar, ranlib utilities, do the following (I put the l-blah into my private ${HOME}/bin directory) % sh -c 'for i in ${LBINS}*; do \ ln -s $i ${HOME}/bin/l-`basename $i`; done' 7.3.2) *******FOR gas-1.38.1l.1******* In the the assembler directory gas-1.38.1l.1: Edit the makefile.linux file and change the appropriate lines to read the following LINUX_INCDIR= HEADERS=-DA_OUT_H=\"${LBINS}../include/linux/a.out.h\" Then type (lots of warnings will appear) % make -f makefile.linux Copy the cross assembler binary manually % cp a386 ${LBINS}as *******FOR gas-2.2 (and above)******* In the the assembler directory do % ./configure --host=sun4 --target=i386-linux-linux % make CC=gcc CFLAGS=-O2 LDFLAGS=-s 7.3.3) Finally make the two links % ln -s ${LBINS}as ${LBINS}../2.4.5/as % ln -s ${LBINS}ld ${LBINS}../2.4.5/ld 7.4) Now in the GCC source directory you extracted on your Sun do the following. % ./configure --host=sun4 --target=i386-linux-linux % make CC=/usr/local/bin/gcc CFLAGS="-O2 -s" \ This may end with a error when building the library libgcc.a ignore it. All you want are the cross compiler binaries in this instance. 7.5) After that finishes, copy the binaries to the proper places... % cp cc1 cc1plus cpp cc1obj ${LBINS}../2.4.5 Copy the front end to the compiler to the bin directory and make a easy link somewhere (maybe your ~/bin) % cp xgcc ${LBINS}gcc % ln -s ${LBINS}gcc ${HOME}/bin/gcc-linux 7.6) Get all your libs from your linux machine % rcp linux_machine:/usr/lib/lib\*a ${LBINS}../2.4.5 % rcp linux_machine:/usr/X386/lib\*a ${LBINS}../2.4.5 % rcp linux_machine:/usr/lib/crt0.o ${LBINS}../2.4.5 7.7) Thats it. Try compiling something. Lots of well written packages will let you do the following (assuming you have the path to your ${HOME}/bin set) % make CC="gcc-linux -O6 -s" RANLIB=l-ranlib AR="l-ar" 7.8) If you want to cross compile shared DLL's then you must also get tsx-11.mit.edu:/pub/linux/packages/GCC/src/tools-2.11.tar.gz Use the Makefile.cross in the tools subdirectory to compile a cross version. Change the definition at the top of the Makefile.cross to look like CROSSBINDIR=${LBINS} CROSSINCDIR=${LBINS}../include Finally change the BINDIR definition. I set it to ${LBINS}../dll/bin This will also create a ${LBINS}../dll/jump for you. Then a % make -f Makefile.cross install should do the business. -------------------------------------------------------------------------------

8) What symbols are automatically defined by Linux's GCC ? Ans: Symbols defined are `linux', `__unix__', `__i386__', `__linux__', `__unix', `__i386', `__linux'. You can get a correct list by using the flag -v to gcc whilst compilation. P.s. One should note that even though the compiler automatically defines "linux" in a program, this is *not* POSIX compliant. Instead __linux__ should be used in programs that need operating-system specific compilation, since __linux__ *is* POSIX compliant. This means you can wrap your linux specific code around (for example) #ifdef __linux__ ...[linux specific code here]... #endif /* ifdef linux */ without adding anything extra to the Makefile defines etc.. You can also add your own defines to the file /usr/lib/gcc-lib/i486-linux/2.5.8/specs -------------------------------------------------------------------------------

9) How do I get over BSD'isms (especially signals, sigvec etc..) when compiling code ? Ans: You can compile your program with -I/usr/include/bsd and link it with -lbsd (i.e. Add -I/usr/include/bsd to CFLAGS and -lbsd to the LDFLAGS line in your Makefile). There is *no* need to add -D__USE_BSD_SIGNAL any more if you want BSD type signal behavior, as this is added automatically when you do the -I/usr/include/bsd -------------------------------------------------------------------------------

10) Where are SIGBUS, SIGEMT, SIGIOT, SIGTRAP, SIGSYS etc ? Ans: Linux is 100% POSIX compliant and these signals are not POSIX signals. As an easy way out you could redefine them to SIGUNUSED. See the definitions in /usr/include/bsd/signal.h However you should note that the lack of these signals *is* compliant with POSIX. Instead of #define'ing to them to SIGUNUSED, new programs should instead say: #ifdef SIGSYS ....[non-posix sigsys code here].... #endif for code that requires the use of SIGSYS (similarly for SIGBUS). Here is a snippet from ISO/IEC 9945-1:1990 (IEEE Std 1003.1-1990), paragraph B.3.3.1.1: "The signals SIGBUS, SIGEMT, SIGIOT, SIGTRAP, and SIGSYS were omitted from POSIX.1 because their behavior is implementation dependent and could not be adequately categorized. Conforming implementations may deliver these signals, but must document the circumstances under which they are delivered and note any restrictions concerning their delivery." -------------------------------------------------------------------------------

11) What is libhard and libsoft ? Ans: These are the libraries for the math emulation routines - the hard if you had hardware to do math (i.e. a 387), or soft if emulation of math routines was done in software. You do *not* need these libraries if you are using a current version of Linux, as math emulation is now done at kernel level - (i.e if you enabled it when you did a `make config' at kernel build time). Otherwise your 387 will do the work. You may safely remove them if your link /lib/libm.so.4 points to a libm.so.4.x.y -------------------------------------------------------------------------------

12) What does the message "can't load library: /lib/libxxx.so, Incompatible version" mean ? Ans: As shared libraries evolve it is necessary to have some sort of version numbering such that a program may be able to determine whether its execution will cause it to crash. This will happen for example if a function call has changed radically or doesn't exist. Say we have a library - libc.so.4.3.3 T T T T / / | \ / / | \ / / | \ Library name / | \ / | \ Major version no. | Patch level. | Minor version no. If the Major version no. changes, then you will only be allowed to execute a program if the Major version number of the current library you are running matches that with which the program was linked with. This means if your program is compiled when you had libc.so.4.3.3 you will not be able to execute it if you get a more recent version of the DLL library, say libc.so.5.1.2. I.e it is no use attempting to create a link from libc.so.5.1.2 to libc.so.4 if your program requires libc.so.4. The Minor version no. is as name suggests, an indication that a minor change has undergone in the shared DLL library, maybe just a new addition of a function, and shows that backward compatability is still retained. If you attempt to use a library whose minor version number is smaller than what the binary was originally compiled with then a warning to this effect will ensue, but normal execution should still be possible. The Patch level no. may be left out totally from the numbering convention. It is usually used just for a typo or small bug fix in the library code. So getting back to the question, it usually means that you are trying to run a binary and you don't have the correct library(ies) installed on your system. To rectify the situation get the latest libs - See questions (3), (19). -------------------------------------------------------------------------------

13) Why are my binaries so huge and how do I reduce them ? Ans: If you want smaller binaries there are a number of things you can do. * Optimize the code - Use the -O2 flag when compiling, * Strip the resultant binary - Use the -s flag at the ld stage. * Make the binary impure - Use the -N flag at the ld stage. A combination of any/all of these may be used. If you want to strip a binary, but don't have the source handy to use the "-s" flag with ld. You can also use the "strip" command. See "man strip" for more information. The linker `ld' will choose by default to link your program to the shared libraries. However if it doesn't find the relevant stubs (i.e. the .sa files) *OR* the these files are unreadable by the user then it will attempt to link static (i.e. to the .a files). This may be a reason why your binaries are so huge. The search path it looks for these .sa and .a libraries are /usr/lib, then /lib and then /. This means you may intersperse the stubs and DLL shared libs anywhere in these directories. More flexibility will soon be available - See also question (20) Also many of the FSF authors believe that we want to debug their programs, and leave the -g option in their Makefiles. The result is that large amounts of debugging symbols are left in and the program is linked statically. Check the Makefile carefully to make sure -g has been removed from either the CFLAGS and/or the LDFLAGS if you are compiling software and you are satisfied with it's operation. -------------------------------------------------------------------------------

14) What does the -N flag do, and when should I use it ? Ans: A demand paged binary can be swapped. If you use the -N option you get an impure executable file which does not have its various segments padded out to page boundaries. Linux can optimize the swapping of sharable (clean) pages by simply "forgetting" them - because it can always reload them directly from the file. Otherwise, it has to physically write them into the swap partition or swap file - which needs some time and uses up disk space. This is usually irrelevant for very small programs, which is why they are often compiled with -N. Large programs (eg. gcc or emacs), or programs which are likely to have multiple instances (like the shell or xterm), should be compiled without -N so that their code pages can be shared cleanly. If you start to run out of memory, the kernel can start to delete unused code pages from demand pages executables as they can always be reloaded later. This is impossible for impure executables. So, if your program is likely to use significant amounts of memory, then don't use -N or the kernel's memory management will be obstructed. Clearly `one-off' programs can all be compiled using this flag - i.e. anything which doesn't stay for long periods of time in memory, say for example hostname, fsck, mkfs, w, etc.. Do *not* use the -N flag on daemons, which by nature are meant to be resident in memory. -------------------------------------------------------------------------------

15) How do I get debugging information into a program ? Ans: You need to compile your program (i.e. all objects) and also link it with the -g flag on - in other words compile *everything* with -g. Debugging still works with -g on for some files only (the ones, which are buggy). More important than using the -g flag is to *not* use the -fomit-frame-pointer flag, as it cheats `gdb' severly. Unfortunately, the shared libs are usually compiled with -fomit-frame-pointer for performance. Therefore, it is wise, to give the -g or the -static flag to the linker, to link with the non-shared libs, when debugging. If you fail to do so, you are usually unable to do a backtrace, when you are caught with a segmentation violation in a system routine. If you end up at the linker stage with a message like Can't find libg.a then you need to get it from the file tsx-11.mit.edu: /pub/linux/packages/GCC/extra-4.5.26.tar.gz However enough debugging information may be gleaned by simply doing % cd /usr/lib; ln -s libc.a libg.a on your linux machine. However, you will not be able to debug any of the library calls unless you use the full libg.a (~2.7Mb). Make sure *NOT* to strip the binary if you want to perform debugging. -------------------------------------------------------------------------------

16) What debuggers are available for Linux ? Ans: Well of course, the best debugger available ever is `gdb'. Look for it at your favorite site. Eg: prep.ai.mit.edu:/pub/gnu/gdb-4.12.tar.gz A Linux precompiled version may be found at: sunsite.unc.edu:/pub/Linux/devel/debuggers/gdb-4.12-bin.tar.gz An X debugger based on this, (i.e. you need gdb installed first), is also available. The source may be found at ftp.x.org:/contrib/xxgdb-1.08.tar.gz Also, the UPS debugger has been ported by Rick Sladkey. It runs under X as well, but unlike xxgdb, it is not merely an X front end for a text based debugger. It has quite a number of nice features, and if you spend any time debugging stuff, you probably should check it out. The Linux precompiled version and patches for the stock UPS sources can be found at: sunsite.unc.edu:/pub/Linux/devel/debuggers/ups-2.45.2-linux-0.1.tar.gz You will need to get the full sources from your nearest X archive or ftp.x.org:/contrib/ups-2.45.2.tar.Z if you wish to rebuild it yourself -------------------------------------------------------------------------------

17) How do I debug a daemon program ? Ans: Simply put, you have to get the daemon program not to fork before you can debug it. However using the debugger `gdb' you can attach to the daemon even *after* it has forked. You do this by telling gdb the process id no. that you want to debug. Use the `attach' command to do this. GDB's integrated online help is useful here. Also if you are not in possession of the source, and the binary is stripped you can obtain the program `strace', attach it to the daemon process id and examine the output produced. This can be useful if you know what you are looking for. Look in sunsite.unc.edu:/pub/Linux/devel/strace/strace-2.tgz -------------------------------------------------------------------------------

18) What is profiling and how do I profile a program ? Ans: Profiling is a way to examine where and which functions time is being spent on, the number of calls made to a certain function and total execution times. It is a good way to optimize code and look at where time is being unnecessarily wasted. To enable profiling all objects and linking must be compiled with the -p flag. See question (15) on where to get the libraries necessary for profiling. To actually get a graph profile you need also the program `gprof'. You will find it included in the binutils package. Again, find it at your favorite Linux archive site. Eg: tsx-11.mit.edu:/pub/linux/packages/GCC/binutils-1.9l.3-as-2.2l.tar.gz -------------------------------------------------------------------------------

19) Is there a way to tell if a binary is linked statically or to a shared library ? Ans: Yes. Use the utility `ldd'. This gives you information on what libraries are required. If no output is generated when you run `ldd' on a program then it indicates the program was linked statically. Eg (1): the command (on my linux system) % ldd /bin/init gives no output meaning init was linked statically. And a good thing too it was linked statically :-) (NOTE: For programs linked with libc.so.4.5.19 and above, the message "statically linked" will be output in this case) Eg (2): the command (on my linux system) % ldd /usr/bin/gs i.e. the ghostscript interpreter gives the following output. libm.so.4 => /lib/libm.so.4.4 (4.0) libX11.so.3 => /lib/libX11.so.3.0 (DLL Jump 3.0pl0) libc.so.4 => /lib/libc.so.4.4 (DLL Jump 4.3) This tells me that the program `gs' was dynamically linked and requires three shared libraries. The numbers in brackets tell me that only one library, (libX11), matches the current version of the library I have when the program was compiled. When `gs' was compiled the math library, (libm), I had was version 4.0 and not a DLL library, but it will happily run with my 4.4 DLL shared version. Similarly my current c library, (libc), is a version greater that when I compiled `gs'. Note: Your version of `ldd' may have a somewhat different output. -------------------------------------------------------------------------------

20) Does Linux have support for LD_LIBRARY_PATH ? Ans: Yes and No, depending on the version of libc you binary was originally compiled with. * Initially LD_LIBRARY_PATH was supported with libraries > than 4.3.3. I.e. the __load.o routine in your stub (/usr/lib/libc.sa) was replaced to cater for this. With binaries compiled using libc version less than 4.4.4, linux's dynamic linker included the loader as a static object in the form of __load.o which appears in the libc.sa stub and automatically gets linked into every binary you build. This means that changes to __load.o take a very long time to propagate and appear in every single binary. So to answer the question is, Yes, it is supported if anything is compiled using library versions greater that 4.3.3, (libc.so.4.3.4 and above), but the upshot is that you will not notice it unless you recompile *all* your binaries. * With libc version 4.4.4 and above, the dynamic loader was infact made dynamic and loads and unloads itself after searching and locating the required libraries. The upshot of this is that binaries are smaller and any changes to the dynamic loader/linker are isolated from libc. You will need to read the manpages to ld.so and ldconfig from the ld.so package. See question (4) under libld.so. Linux's LD_LIBRARY_PATH is very security concious, and do NOT expect to work the way Sun-OS do it or the way you'd like it to. Primarily the difference with Sun-OS's LD_LIBRARY_PATH use is the fact that during compilation (linking) stage, the LD_LIBRARY_PATH is parsed to find valid libraries to link to and these are *recorded* within the incomplete binary produced. Hence at runtime the binary knows where to look for the shared libraries before it looks up LD_LIBRARY_PATH, (and often it never parses LD_LIBRARY_PATH at all, as it finds the shared libraries first in the recorded path), thus reducing overhead. Linux on the other hand does NOT record this information, but instead searches at runtime (execution) for libraries it need to link to. When a binary is executed on Linux it first searches /usr/lib, then /lib and then / for a library to runtime link to if you do *not* have any LD_LIBRARY_PATH. This can be referred to as the "trusted search path". Note that / is not really a search path, but was put in for backward compatability as some users were building shared DLL's using names like "/lib/libfoo.so" so uselib() would now do (1) uselib("/usr/lib//lib/libfoo.so.x") ---- fails (2) uselib("/lib//lib/libfoo.so.x") ---- fails again (3) uselib("//lib/libfoo.so.x") ---- succeeds.!! So don't actually put your DLL's in / :-) Now if you *do* have a LD_LIBRARY_PATH and you are root, (user with uid 0), then LD_LIBRARY_PATH is searched followed by the trusted search path. If on the other hand you are a normal user, (uid != 0), and the binary to be executed is a suid executable, then the libc.so.x and necessary libraries are force loaded from somewhere in the trusted search path. The LD_LIBRARY_PATH is ignored, (in fact reset totally). This stops a normal user from emulating his own, for example, setuid() calls from a libc library (s)he created. Finally if you are a normal user and the binary to be executed is a "normal" binary, then LD_LIBRARY_PATH is searched first for the libraries required. If the library is NOT found in the users LD_LIBRARY_PATH then the search path is set to the "trusted search path" and the search carries on. This gets over the problems of incorrect/silly LD_LIBRARY_PATH settings and still allows these kind of nubile users to execute binaries. -------------------------------------------------------------------------------

21) My program wants /lib/cpp ! Where can I get it from ? Ans: cpp appears in /usr/lib/gcc-lib/i486-linux/2.5.8 (the gcc version numbers may have changed when you read this) You need to do the following % cd /lib; ln -sf /usr/lib/gcc-lib/i486-linux/2.5.8/cpp ** Change the 2.5.8 to whatever version of GCC your are using. ** Change the i486 to i386 if using the 386 compiler An alternative, and possibly better solution is this: % cat > /lib/cpp #!/bin/sh cc -E "$@" Ctrl-D[EOF] This way /lib/cpp won't stop working when you switch to a newer gcc version and delete the old one. -------------------------------------------------------------------------------

22) Where are <float.h>, <limits.h>, <varargs.h>, <stdarg.h> and <stddef.h> ? Ans: These files depend on the version of your compiler. Theyfore they are hidden in a compiler directory. /usr/lib/gcc-lib/i486-linux/2.5.8/include ** Change the 2.5.8 to whatever version of GCC your are using. ** Change the i486 to i386 if using the 386 compiler -------------------------------------------------------------------------------

23) My program wants to include <linux/foo.h> but cannot find it, where is it ? Ans: As some of the includes are kernel version dependent, they are thus kept along with the kernel releases. You need to get the latest kernel sources, unpack them and then make appropriate links. If say you unpacked the kernel source in /usr/src such that you have a /usr/src/linux directory, then you should do the following: % cd /usr/include % ln -sf /usr/src/linux/include/linux % ln -sf /usr/src/linux/include/asm The MCC release does not initially have these links, and hence one can install a new kernel source tree, and still be using the old include files. Watch out for this. -------------------------------------------------------------------------------

24) Do we have the function foo() in our libraries ? Ans: An easy way to check out whether a function is supported in a certain library is to do the following, say you are unsure whether flock() is supported ... % nm /usr/lib/libc.a | grep flock If you get something like 00000000 T flock flock() is defined in libc.a/libc.sa. If you only get lines like 00000000 U flock it only indicates a reference to flock(). The `U' means that flock is defined elsewhere and you need to include the library where it is defined such that the reference can be resolved. -------------------------------------------------------------------------------

25) How do I port program XXX to Linux ? Ans: Gone are the days when one had to `port' a program to Linux. These days if something hasn't been ported to Linux then it is not worth having :-) Seriously though, in general only minor changes are needed to the sources to get over Linux's 100% POSIX compliance. It is also worthwhile passing back any changes to authors of the code such that in the future only `make' need be called to provide a working executable. One of the most frequent problems is that some common functions are defined as macros in Linux's header files and the preprocessor will refuse to parse similar prototype definitions in the code. Common ones are atoi() and atol(). There is another common problem: "sprintf(string, fmt, ...)" returns a pointer to string on most unixes, while linux returns the number of characters, which were put into the string. Other problems tend to arise from the fact, that GCC is an ANSI compiler. Most important changes are for the preprocessor. Adding the option: -traditional is often the only (but poor) solution. | Some other worthy comments are noted below from Bruno Haible: | This is an attempt to describe some of the problems that may arise when porting Unix software to Linux. We assume the software is written in C. Linux (i.e. its system calls and C library functions) is as closely POSIX compliant as possible. This makes this list very short. Problem 1: The select() timeout ------------------------------- Symptom: A program that should only poll for input becomes a CPU hog. Problem: The select() system call. The timeout parameter was classically used read-only by the system. Some manual pages already notes three years ago: select() should probably return the time remaining from the original timeout, if any, by modifying the time value in place. This may be implemented in future versions of the system. Thus, it is unwise to assume that the timeout pointer will be unmodified by the select() call. If you do not take this advice seriously you get a zero timeout written back to your timeout structure, which means that future calls to select() using the same timeout structure will immediately return. Fix: Put the timeout value into that structure every time you call select(). Change code like struct timeval timeout; timeout.tv_sec = 1; timeout.tv_usec = 0; while (some_condition) { select(n,readfds,writefds,exceptfds,&timeout); } to struct timeval timeout; while (some_condition) { timeout.tv_sec = 1; timeout.tv_usec = 0; select(n,readfds,writefds,exceptfds,&timeout); } Problem 2: Interrupted system calls ----------------------------------- Symptom: When a program is stopped using Ctrl-Z and then restarted - or in other situations that generate signals: Ctrl-C interruption, termination of a child process etc. - it complains about "interrupted system call" or "write: unknown error" or things like that. Problem: The system call the program was executing has been interrupted to process the signal, and then it returned -1 and set errno = EINTR. The program then was likely to draw bad conclusions from that. Explanation: Your program has signal handlers installed (using signal(), sigaction() or sigvec()). The signal occurred, and your signal handler was invoked. In other Unix systems, this usually happens asynchronously or in a few slow system calls: When a signal is caught during the execution of system calls such as read(2), write(2), open(2) or ioctl(2) on a slow device (such as a terminal, but not a file), during a pause(2) system call or a wait(2) system call that does not return immediately because a previously stopped or zombie process already exists, the signal-catching function is executed and the interrupted system call then returns a -1 to the calling process with errno set to EINTR. Linux (following POSIX) checks for signals and may execute signal handlers * asynchronously (at a timer tick), * on return from *any* system call, * during the execution of the following system calls: select(), pause(), connect(), accept(), read() on terminals or sockets or pipes or /proc files, write() on terminals or sockets or pipes or line printer, open() on FIFOs or PTYs or serial lines, ioctl() on terminals, fcntl() with command F_SETLKW, wait4(), syslog(), any TCP or NFS operations. [For other operating systems you may have to include the system calls creat(), close(), getmsg(), putmsg(), msgrcv(), msgsnd(), recv(), send(), wait(), waitpid(), wait3(), tcdrain(), sigpause(), semop() to this list.] In the last two cases and assuming the program's signal handler returns, the system call returns -1 and sets errno to EINTR. If the SA_RESTART flag is set for the corresponding signal, however, in most cases the system call is automatically restarted (continued) after execution of the signal handler, and your program won't see any EINTR. You may ask why this is not the default behaviour. This is because returning and setting EINTR is more powerful: it gives your program the opportunity to immediately react on every signal it receives. System calls are no longer "dark tunnels". Note that in some versions of BSD Unix the default behaviour is to restart system calls. To get system calls interrupted you have to use the SV_INTERRUPT or SA_INTERRUPT flag. You may choose between two fixes. Fix 1: For every signal handler that you install, add SA_RESTART to the sigaction flags. For example, change signal (sig_nr, my_signal_handler); to signal (sig_nr, my_signal_handler); { struct sigaction sa; sigaction (sig_nr, (struct sigaction *)0, &sa); #ifdef SA_RESTART sa.sa_flags |= SA_RESTART; #endif #ifdef SA_INTERRUPT sa.sa_flags &= ~ SA_INTERRUPT; #endif sigaction (sig_nr, &sa, (struct sigaction *)0); } Note that while this applies to most system calls, you must still check for EINTR on read(), write(), ioctl(), select(), pause(), connect(). Here are two examples for read() and ioctl(), Original piece of code using read() int result; while (len > 0) { result = read(fd,buffer,len); if (result < 0) break; } becomes int result; while (len > 0) { result = read(fd,buffer,len); if (result < 0) { if (errno != EINTR) break; } } and; Original piece of code using ioctl() int result; result = ioctl(fd,cmd,addr); becomes int result; do { result = ioctl(fd,cmd,addr); } while ((result == -1) && (errno == EINTR)); -------------------------------------------------------------------------------

26) I think I have found a bug in gcc/library foo, what do I do now ? Ans: Have you really ? Well first try and narrow the code down to a few lines and see if the program still fails/doesn't work as expected. Does the same behavior occur both with a static and shared version ? (i.e. is it a problem with the DLL libs, or the static libs) Have you access to another platform running gcc ? In other words is the problem a GCC one as opposed to a Linux/GCC one ? If so you may want to post to one or more of the relevant USENET newsgroups Is the problem in the math emulator ? If so you could email Bill Metzenthen (apm233m@vaxc.cc.monash.edu.au) the writer of the emulator code. Finally you could try emailing linux-bugs@sunsite.unc.edu, myself (mitchum.dsouza@mrc-apu.cam.ac.uk) or even HLU. -------------------------------------------------------------------------------

27) Why are shared libraries so large in comparison to their static counterparts ? Ans: Shared libraries reserve space for future expansion in the form of `holes' which can be made to take no disk space. A simple `cp' call or using the program `makehole' will achieve this. You can also strip your libraries after you build them. -------------------------------------------------------------------------------

28) What are .sa file I see in /usr/lib ? Ans: The .sa files are the stubs to the shared libraries and contain all global variables from a certain library, and pointers to functions required for run time linking. See also question (13). -------------------------------------------------------------------------------

29) Where can I get Objective C for Linux ? Ans: Objective C is in releases of gcc for Linux versions gcc-2.4.0 and above. This is not currently fully tested at the moment. The latest version may be obtained from tsx-11.mit.edu:/pub/linux/packages/GCC/gcc-2.5.8-p2.tar.gz -------------------------------------------------------------------------------

30) What does the message "Internal compiler error: cc1 got fatal signal 11,4" mean ? Ans: Gcc is probably the biggest memory hog you likely to run on your machine and it will surely eat up a lot of your RAM. Usually a fatal signal 11 will mean some sort of parity errors in your RAM or other hardware faults. I had this once when `cc1' got corrupted due to a race condition and bad blocks on my hard disk. There have also been reports that overheating chips, (not french fries), can also produce such errors. And watch for poor IDE controller/drive combos that are being run faster than the standard 8MHz AT bus clock. These can give the same errors by causing corruption of the swap space. Usually, a signal 11 (segmentation violation) means that a process tried to access memory out of its process space, or tried to write into a read-only location. Sometimes, this signal is caused by software bugs, not by hardware faults (or your system would hang repeatedly, because the same thing happened to the kernel). With gcc 2.3.3, some people could reproduce a lot of "signal 11"'s. A "fatal signal 4" has been reported to be generated due to lack of memory (happened on a 4MB system). Also it can mean a failure in one of the `ld' or `as' stages. Try recompiling whatever with a -v flag to gcc and see if it is failing in one of the cc1, cpp, as or ld stages possibly. -------------------------------------------------------------------------------

31) What is a libc-lite ? Ans: A libc-lite is a light-weight version of the libc library built such that it will fit on a floppy and suffice for all of the most menial of UNIX tasks. It does *not* include curses, dbm, termcap etc code. If your /lib/libc.so.4 is linked to a lite lib, you are advised to replace it with a full version. See question (3) on where it is available from. -------------------------------------------------------------------------------

32) Does Linux libraries have SHADOW Password support, and how do I switch it on/off ? Ans: Yes. You need to compile programs with the defines SHADOW_PWD in place, and link it with the shadow library - available separately in: sunsite.unc.edu:/pub/Linux/distributions/SLS/a4/shadow.tgz This means adding -DSHADOW_PWD to the CFLAGS line in the Makefile, and -lshadow in the LDFLAGS line. You may also have to change the source a bit, as the "crypt()" in the shadow support is implemented as a macro and not a function. Hence any "extern int crypt()" may trip it up. This means that there is NO WAY of switching shadow password'ing on/off without having to compile *all* necessary binaries which use the getpwent(), setpwent() etc routines. NOTE: At some point in the future the shadow routines may be integrated into the standard C library. -------------------------------------------------------------------------------

33) Can't find math.h routines ! My program compiles but cannot find log(), sin(), etc.., HELP !! Ans: When you compile a program using certain functions, you *must* also link the program to the appropriate library. This means for math functions you have to include libm.a at the linker stage, i.e. add -lm to the LDFLAGS, for curses functions add -lcurses, for dbm functions add -ldbm etc... Always put the -lm flag after the objects. So this is no good: % gcc -lm -o math_prog math_prog.c as the math functions will not be resolved. Instead do: % gcc -o math_prog math_prog.c -lm -------------------------------------------------------------------------------

34) Is there a manual for GCC? If so, where do I get it, and how do I print it out ? Ans: There is a file on sunsite in the GCC directory sunsite.unc.edu:/pub/Linux/GCC/gcc-man.tar.z If you want a full printed manual for GCC, then you will have to get the full source from your local ftp site that carries GCC and other FSF goodies. You will require TeX to make the manual from the GCC source distribution. If it is the library function calls you are looking for, then you need to get the full source for glibc. This will be on the same ftp archive that you found the sources for GCC. Again, you will need TeX to generate the manual. Be warned that this manual is about 900 pages long. Save a tree and keep it online as a dvi file. Both of the above packages also come with "info" files, that can be viewed using Gnu info, xinfo, or emacs. "info" files are a hyper- text based information system. -------------------------------------------------------------------------------

35) I get the message "Undefined symbol _bsd_ioctl". Where is this anyhow ? Ans: You forgot to include the bsd library /usr/lib/libbsd.a into your program at the linking stage. Solution: Add -lbsd to the Makefile LDFLAGS line. (or add it manually if it doesn't have a LDFLAGS line) -------------------------------------------------------------------------------

36) If I upgrade versions, can I get rid of the old stuff from /usr/lib/gcc-lib/i[34]86-linux/<old-version> ? Ans: Well unless you are testing gcc releases it is fairly safe to get rid of any older versions in that directory. You can compile with older versions of gcc using "gcc -V <old-version> -------------------------------------------------------------------------------

37) [HELP] where is libipc.a ? Needed for dosemu 0.49.. Ans: The Inter Process Communication (IPC) functions are included as standard in libc as of libc.so.4.4.1. This means if you have libc.so.4.4.1 and above, you do not need -lipc and can remove this line from the Makefile. If you do not have libc.so.4.4.1 and its related stub libc.sa then you need to upgrade you libraries. -------------------------------------------------------------------------------

38) XXX won't compile: _daemon undefined, help!! Ans: daemon() is in libbsd.a. Just add -lbsd to your Makefile LDFLAGS line. -------------------------------------------------------------------------------

39) [HELP] ar and libraries. Linking fails although symbol appears in library. Ans: There is a known bug in `ar' where sometimes `ranlib' does not generate a correct table. This can be worked around with the commands % ar -dv libfoo.a __.SYMDEF % ranlib libfoo.a -------------------------------------------------------------------------------

40) HELP! newbie gets warning message "libc.so.4: incompat. minor ver no." Ans: You need a shared library upgrade. See questions (12) and (3) for more details. -------------------------------------------------------------------------------

41) Where can I find `lint' to check my c programs before compilation ? Ans: There is no `lint' or the likes for checking programs. Instead use the plethora of gcc options for checking your programs. Read the manual pages for the variety options. The most useful % gcc -Wall foo.c will warn you of most of the possible problems that might occur. -------------------------------------------------------------------------------

42) My program needs sgtty.h where is it ? Ans: It is in /usr/include/bsd directory. So just add the line -I/usr/include/bsd to your CFLAGS line in the Makefile when compiling. -------------------------------------------------------------------------------

43) How do I stop or start core files being produced on SIGSEGV's ? Ans: This is not really a GCC question, but more a shell one. Anyhow to stop core files being produced totally: In C-shell `csh' (tcsh) % limit core 0 In Bourne shell `sh' (bash) % ulimit -c 0 To start corefiles when you recieve signal 11 (SEGV): In C-shell `csh' (tcsh) % limit core unlimited In Bourne shell `sh' (bash) % ulimit -c unlimited -------------------------------------------------------------------------------

44) What does the message "can't load dynamic linker `/lib/ld.so'" mean ? Ans: This means you haven't installed the dynamic linker/loader. See question (4) under libld.so on where to obtain this from. -------------------------------------------------------------------------------

45) What is the difference between -O2 and -O6 optimizations ? Ans: Nothing at present. If you look at the source code for GCC (eww! yuck!) with an i386/i486 host/target, you will see that -Ox for x>=2 does the same thing. In fact it is a bad thing to use x>2 in your Makefiles, because if GCC implements -O3 on Intel targets in the future, it may be an optimization that breaks your code. -------------------------------------------------------------------------------

46) How can I check an unknown binary to see if it is a trojan horse ? Ans: First, if you are worried that it is going to hose your machine, *don't* run it. (At least not as root!) Try and find the source and recompile it. Other than that, you might be able to get some information on it by typing "strings <filename> | less". If you are game enough to run it, you can use `strace' to see if it is doing anything nasty. See question (17) on its whereabouts. -------------------------------------------------------------------------------

47) Where are the sources to the C library - how do I rebuild it ? Ans: Look in tsx-11.mit.edu:/pub/linux/pagkages/GCC/libc-4.5.26.tar.gz If you want shared libraries you will also need the dll tools package. See question (5) on where to obtain this from. To rebuild, unpack the sources, make sure you have the corresponding include files for that version of the C library, and then under libc-linux directory do the following % ./configure Answer all the questions at this point. If you are building on a native linux machine (i.e not cross-compiling) you can just type <return> at this point (i.e. accept the default values). Then type % make NOTE: If you are cross-compiling, it is probably a wise idea to keep a copy of the configure generated file `config.in' for future use. You can just copy the old version into the libc-linux directory and type `make'. -------------------------------------------------------------------------------

48) Where are the definitions of FD_* stuff ? Ans: Just include <sys/time.h> and these macros will be included. -------------------------------------------------------------------------------

49) When linking with option -g I get undefined ___fpu_control and ___setfpucw ? /usr/lib/crt0.o Undefined symbol ___fpu_control reference from text segment. /usr/lib/crt0.o Undefined symbol ___setfpucw reference from text segment. what's wrong? Ans: You have updated your crt0.o libc.sa and libc.a from a recent copy of the linux libc, but you have still an old libg.a around. If you really want to get a static binary (this is implied by -g) with a debug library, you should get and install libg.a. See question (15) on the whereabouts of this. -------------------------------------------------------------------------------

50) Where can I get the tools to Internationalize my library/application ? Ans: Get the file sunsite.unc.edu:/pub/Linux/utils/nls/cat-pack.tar.gz and follow the instructions there. User contributed catalogs in various languages may be found in sunsite.unc.edu:/pub/Linux/utils/nls/catalogs and placed in the Incoming directory under there. NOTE: Internationalization tools and functions are only available in libraries greater than version 4.4.4 (i.e. libc.so.4.5.x and above) NOTE: In this context `Internationalization' is used loosely and as of linux pl14 supports only Latin-1/ISO-8859-1 charsets. -------------------------------------------------------------------------------

51) The DLL tool `mkimage' fails to find libgcc. Help!!! Ans: As of libc.so.4.5.x and above, libgcc is no longer shared. Hence you must replace occurences of `-lgcc' on the mkimage line with `gcc -print-libgcc-file-name` or for short `gcc --print` With the backquotes intact. -------------------------------------------------------------------------------

52) How do I get rid of "__NEEDS_SHRLIB_libc_4 multiply defined" messages ? Ans: As of libc.so.4.5.x and above, libgcc is no longer shared. Thus you MUST delete all /usr/lib/libgcc* files. % rm -f /usr/lib/libgcc* -------------------------------------------------------------------------------

53) What is this QMAGIC thing everyone is talking about ? Ans: QMAGIC is an executable format just like your standard a.out (which are ZMAGIC) binaries, but which leaves the first page unmapped. This allows for easier NULL dereference trapping as no mapping exists in the range 0-4096. As a side effect your binaries are nominally smaller as well (~1K). Your `file' command will be able to identify a QMAGIC binary if the proper entry has been added to your /etc/magic file. I have distributed suitable entries to most channels. -------------------------------------------------------------------------------

54) How do I generate a QMAGIC executable/library ? Ans: You need the lastest `ld' binary or patches to the source to be able to generate QMAGIC executables. This will be distributed in the `binutils-1.9l.3-as-2.2l.tar.gz' file - See question (2). To build a QMAGIC executable: Add one of the following to your LDFLAGS line in the Makefile LDFLAGS = -Wl,-qmagic or LDFLAGS = -Xlinker -qmagic To build a QMAGIC library: Sorry, not fully supported by the `mkimage' tool at the moment. -------------------------------------------------------------------------------

55) Is it possible to turn the "warning using incompatable library version xxx" messages off ? Ans: Yes. If you have ld.so version 1.4 and above you may set the environment variable LD_NOWARN to supress warning messages. Note: fatal mesages are still output. In csh (tcsh): setenv LD_NOWARN In sh (bash): export LD_NOWARN=true -------------------------------------------------------------------------------

56) Is GNU's glibc 1.06 texinfo manual pages relevant to Linux's libc? Ans: Yes, except for the stdio internals. -------------------------------------------------------------------------------

57) Can I sell my application if it was compiled within linux ?? (a) It is legal to sell your applications. You may take as much money as you want. (b) Simply using a GNU tool to develop your application does not affect your copyright to your applications. This includes (c) However, your copyright is affected, if you include code from other GNU applications into yours. In this case, you have to put the resulting ("derived") work under the GNU copyleft. That means, that you have to release source code upon request, and that your customer(s) may distribute (and/or sell!) copies of your source code and/or binary. (d) 99% of all C programs written are linked against the C library. Linking means, that you include GNU code into your program. However, the C library is released under special terms (GNU Library Public License, GLPL), which allows linking as an exception to what is said in c). You can link with the C library at will, but you have to provide your program in a form, that the user can update the library. In case of shared linking, this is not a problem, but if you want (or must) link with static libraries, you must provide your program in a form, which has not yet been linked with the static library (say, link all your .o-files into one big .o using "ld". Take a look at the kernel sources to see how it works). (e) What is said at point a) is always true: you may sell your application, whether or not it has to be distributed under the GNU copyleft, for as much money as you want. -------------------------------------------------------------------------------

58) Why do I get an "Assertion failure" message when rebuilding a DLL ?? Ans: This cryptic message most probably means that one of your jump table slots has overflowed because too little space has been reserved in the original jump.vars file. You can locate the culprit(s) by running the `getsize' command provided in the tools-x.y.tar.gz package. See question (5) on where to obtain this from. The only solution in this case may be to bump up the major version number of the library forcing it to be backward incompatible. =============================================================================== Acknowledgements: (in no order) H.J.Lu Dirk Hohndel David Engel Eric Youngdale Bill Metzenthen Rik Faith Steven S. Dick Bruno Haible Andrew Tefft Kai Petzke Tuomas J Lukka Fergus Henderson Paul Gortmaker Olaf Flebbe and of course Linus Torvalds =============================================================================== N.B. Please do not feel offended if your name has not appeared here and you have contributed however significantly/insignificantly. It is entirely my fault. Email me and I will rectify it. =============================================================================== Please help in making this FAQ the definitive answer repository of Linux GCC queries by e-mailing questions, (and answers if you have them), corrections and additions to me Mitchum DSouza <m.dsouza@mrc-apu.cam.ac.uk>