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kld(3)                                                                  kld(3)




NAME

       kld_load,    kld_load_from_memory,    kld_lookup,    kld_forget_symbol,
       kld_unload_all,    kld_load_basefile,    kld_load_basefile_from_memory,
       kld_address_func, kld_set_link_options - programmatically link edit and
       load driver object files


SYNOPSIS

       #include <kld.h>

       #ifdef __DYNAMIC__
       __private_extern__ long kld_load_basefile(
            const char *base_filename);

       __private_extern__ long kld_load(
            struct mach_header **header_addr,
            const char *object_filename,
            const char *output_filename);

       __private_extern__ long kld_load_from_memory(
            struct mach_header **header_addr,
            const char *object_name,
            char *object_addr,
            long object_size,
            const char *output_filename);
       #endif /* __DYNAMIC__ */

       #ifdef __STATIC__
       __private_extern__ long kld_load_from_memory(
            struct mach_header **header_addr,
            const char *object_name,
            char *object_addr,
            long *object_size);
       #endif /* __STATIC__ */

       __private_extern__ long kld_load_basefile_from_memory(
            const char *base_filename,
            char *base_addr,
            long base_size);

       __private_extern__ long kld_lookup(
            const char *symbol_name,
            unsigned long *value);

       __private_extern__ long kld_forget_symbol(
            const char *symbol_name);

       __private_extern__ long kld_unload_all(
            long deallocate_sets);

       __private_extern__ void kld_address_func(
            unsigned long (*func)(unsigned long size, unsigned long headers_size));

       #define KLD_STRIP_ALL    0x00000000
       #define KLD_STRIP_NONE   0x00000001

       __private_extern__ void kld_set_link_options(
           unsigned long link_options);


DESCRIPTION

       The kld package is designed for loading kernel drivers both by the ker-
       nel  for  loading  boot drivers and kextload for loading other drivers.
       The library that contains the kld package  is  linked  with  the  -lkld
       linker  flag.   For  the  kernel  when linked with the -static flag the
       -lkld linker flag will link the library  libkld.a.   And  for  kextload
       when  linked with the -dynamic flag the -lkld linker flag will link the
       library libkld.dylib.

       For    the    kernel     the     kld_load_basefile_from_memory,     and
       kld_load_from_memory APIs are provided in the library libkld.a compiled
       with the -static compiler flag.  Using this library one must define the
       following variable:
            extern char *kld_basefile_name;
       which is the the name of the base file used for error messages.


       For   kextload  the  kld_load_basefile,  kld_load_basefile_from_memory,
       kld_load, and kld_load_from_memory APIs are  provided  in  the  library
       libkld.dylib compiled with the -dynamic compiler flag.

       kld_load  or  kld_load_from_memory link edits and loads the file speci-
       fied by object_filename or memory pointed to by  obj_addr  respectively
       to the base file that was previous loaded with a call to kld_load_base-
       file or kld_load_basefile_from_memory.

       If the program, in this case the kernel, is to allow the loaded  object
       files   to  use  symbols  from  itself,  it  must  be  built  with  the
       -seglinkedit option of the link editor, ld(1), in  order  to  have  its
       symbol table mapped into memory.

       The  symbol  table may be trimmed to limit which symbols are allowed to
       be referenced by loaded objects.  This can be accomplished with the  -s
       filename  option  to  strip(1).   For the routines described here, only
       global symbols are used, so local symbols can be removed  with  the  -x
       option to ld(1) or strip(1).  Doing so saves space in the final program
       and  vastly  decreases  the  time  spent   by   the   first   call   to
       kld_load_from_memory  or kld_load_basefile.  (This is true of the first
       call in the program, as well as the first call after an  invocation  of
       kld_unload_all).    The   first   call   to   kld_load_from_memory   or
       kld_load_basefile must go through all the symbols  of  the  program  or
       basefile,  so if the program has been compiled for debugging (for exam-
       ple), it can take orders of magnitude longer.

       Since the objects loaded with kld_load or kld_load_from_memory can only
       use  symbols that appear in the executable program, if the program uses
       a library and wants to make all the symbols in that  library  available
       to  the  loaded  objects, it must force all of the library symbols into
       the executable.  This can be done for all libraries with the  -all_load
       option  to  ld(1) when building the executable.  This will copy all the
       library code into the executable.


       The object file being loaded will only be successful if  there  are  no
       link  edit  errors  (undefined symbols, etc.).  If an error occurs, the
       object file is unloaded automatically.  If errors occur the  user  sup-
       plied routine will be called:
            extern void kld_error_vprintf(const char *format, va_list ap);

       If  the  link  editing  and  loading  is successful, the address of the
       header of what was loaded is returned through the  pointer  header_addr
       (if  it  isn't NULL).  If kld_load is successful and the parameter out-
       put_filename isn't NULL, an object file is written  to  that  filename.
       This  file  can  be  used with the gdb(1) add-file command to debug the
       code in the dynamically loaded object.  The kld_load function returns 1
       for success and 0 for failure.  If a fatal system error (out of memory,
       etc.) occurs, all future calls  to  kld_load  and  the  other  routines
       described here will fail.

       kld_load_from_memory()  is  similar  to kld_load(), but works on memory
       rather than a file.  The argument object_name is  the  name  associated
       with  the  memory and is used for messages.  (It must not be NULL.) The
       arguments object_addr and object_size are the memory address  and  size
       of the object file.  kld_load_from_memory() only allows one thin object
       file (not an archive or ``universal'' file) to be loaded.

       kld_lookup() looks up the specified symbol name and returns  its  value
       indirectly  through  the  pointer  value.  It returns 1 if it finds the
       symbol, and 0 otherwise.  If any errors occur it also  calls  the  user
       supplied  kld_error_vprintf  routine  (For  kld_lookup,  only  internal
       errors can result.)

       kld_forget_symbol() causes this package to forget the existence of  the
       specified  symbol  name.   This  allows  a new object to be loaded that
       defines this symbol.  All objects loaded before this call will continue
       to  use  the  value  of the symbol in effect at the time the object was
       loaded.  It returns 1 if it finds the symbol and 0 otherwise.   If  any
       errors  occur it also calls the user supplied kld_error_vprintf routine
       (For this routine, only internal errors can result.)

       kld_unload_all() clears out all allocated data structures used by these
       routines.   If  the parameter deallocate_sets is non-zero, the function
       also unloads all objects that were loaded.  If deallocate_sets is  zero
       the  object  sets  aren't unloaded, and the program can continue to use
       the code and data loaded.   However,  further  calls  to  the  routines
       described  here will no longer know about the symbols in those objects.
       If objects aren't to be allowed access  to  each  other's  symbols,  an
       kld_unload_all  call between calls to kld_load allows the objects to be
       loaded without fear of global symbol names'  clashing.   kld_unload_all
       returns  1  if  it  is successful and 0 otherwise.  If any errors occur
       also calls the user supplied kld_error_vprintf routine.

       The argument to kld_load_basefile specifies a base file,  whose  symbol
       table  is taken as the basis for subsequent kld_load's.  kld_load_base-
       file_from_memory is an alternate interface that allows mapped  ``thin''
       object  image to be specified rather than a file.  The base file may be
       a ``universal'' file, and must contain an architecture that would  exe-
       cute  on the host; otherwise, it is an error.  If the file is a univer-
       sal file, the ``best'' architecture (as  defined  by  what  the  kernel
       exec(2) would select) is used as the base file.  kld_load_basefile must
       be invoked before any call  to  kld_load.   Alternatively,  it  can  be
       called after kld_unload_all, which unloads the base file.  This call is
       intended to be used when a program is dynamically loading  object  sets
       into a program other than itself, where base_filename contains the sym-
       bol  table  of  the  target  program.   The  routine  kld_address_func,
       described next, would also be used.

       kld_address_func  is passed a pointer to a function, func, that will be
       called from kld_load.  The parameter values that kld_load  will  supply
       to  func  are  the  size  of  the  memory required for the object being
       loaded, and the size of the headers (which are  also  included  in  the
       calculation of size).  The function specified by func should return the
       address where the output is to be  link  edited.   kld_address_func  is
       intended  to be used when a program is dynamically loading objects into
       a program other than itself; the function allows it to pick  the  place
       in the address space of the target program.

       kld_set_link_options  is  passed  a mask of options, link_options, that
       are used to control some aspects of the following kld_load  operations.
       Passing  KLD_STRIP_NONE  will  stop kld from stripping symbols from the
       output in all cases. By default all symbols  are  stripped  for  kernel
       loads   and   when   output_filename   is   NULL   for  kld_load()  and
       kld_load_from_memory()



UNIVERSAL FILE SUPPORT

       All functions that accept object files or archives also  accept  ``uni-
       versal''   files,   except   for   the  restrictions  noted  above  for
       kld_load_from_memory and kld_load_basefile.



SEE ALSO

       ld(1), strip(1), gdb(1)



BUGS

       There exists one semantic link edit problem with respect to common sym-
       bols.   If  an object file is loaded that has common symbols left after
       the symbols have been merged, kld_load  has  to  allocate  storage  for
       these  symbols  for  the code to run without error.  The problem occurs
       if, on a later call  to  kld_load,  one  of  the  common  symbols  that
       kld_load  allocated appears in an object file as a defining symbol (not
       a common or undefined symbol).  In this case, kld_load will report  the
       symbol  as  being  multiply  defined.   However, if this combination of
       object files were statically linked, no error would occur.



Apple Computer, Inc.             July 28, 2005                          kld(3)

Mac OS X 10.6 - Generated Thu Sep 17 20:21:09 CDT 2009
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