@c -*- Texinfo -*- @node Syscalls @chapter System Calls @cindex linking the C library The C subroutine library depends on a handful of subroutine calls for operating system services. If you use the C library on a system that complies with the POSIX.1 standard (also known as IEEE 1003.1), most of these subroutines are supplied with your operating system. If some of these subroutines are not provided with your system---in the extreme case, if you are developing software for a ``bare board'' system, without an OS---you will at least need to provide do-nothing stubs (or subroutines with minimal functionality) to allow your programs to link with the subroutines in @code{libc.a}. @menu * Stubs:: Definitions for OS interface * Reentrant Syscalls:: Reentrant covers for OS subroutines @end menu @node Stubs @section Definitions for OS interface @cindex stubs @cindex subroutines for OS interface @cindex OS interface subroutines This is the complete set of system definitions (primarily subroutines) required; the examples shown implement the minimal functionality required to allow @code{libc} to link, and fail gracefully where OS services are not available. Graceful failure is permitted by returning an error code. A minor complication arises here: the C library must be compatible with development environments that supply fully functional versions of these subroutines. Such environments usually return error codes in a global @code{errno}. However, the Red Hat newlib C library provides a @emph{macro} definition for @code{errno} in the header file @file{errno.h}, as part of its support for reentrant routines (@pxref{Reentrancy,,Reentrancy}). @cindex @code{errno} global vs macro The bridge between these two interpretations of @code{errno} is straightforward: the C library routines with OS interface calls capture the @code{errno} values returned globally, and record them in the appropriate field of the reentrancy structure (so that you can query them using the @code{errno} macro from @file{errno.h}). This mechanism becomes visible when you write stub routines for OS interfaces. You must include @file{errno.h}, then disable the macro, like this: @example #include #undef errno extern int errno; @end example @noindent The examples in this chapter include this treatment of @code{errno}. @ftable @code @item _exit Exit a program without cleaning up files. If your system doesn't provide this, it is best to avoid linking with subroutines that require it (@code{exit}, @code{system}). @item close Close a file. Minimal implementation: @example int close(int file)@{ return -1; @} @end example @item environ A pointer to a list of environment variables and their values. For a minimal environment, this empty list is adequate: @example char *__env[1] = @{ 0 @}; char **environ = __env; @end example @item execve Transfer control to a new process. Minimal implementation (for a system without processes): @example #include #undef errno extern int errno; int execve(char *name, char **argv, char **env)@{ errno=ENOMEM; return -1; @} @end example @item fork Create a new process. Minimal implementation (for a system without processes): @example #include #undef errno extern int errno; int fork() @{ errno=EAGAIN; return -1; @} @end example @item fstat Status of an open file. For consistency with other minimal implementations in these examples, all files are regarded as character special devices. The @file{sys/stat.h} header file required is distributed in the @file{include} subdirectory for this C library. @example #include int fstat(int file, struct stat *st) @{ st->st_mode = S_IFCHR; return 0; @} @end example @item getpid Process-ID; this is sometimes used to generate strings unlikely to conflict with other processes. Minimal implementation, for a system without processes: @example int getpid() @{ return 1; @} @end example @item isatty Query whether output stream is a terminal. For consistency with the other minimal implementations, which only support output to @code{stdout}, this minimal implementation is suggested: @example int isatty(int file)@{ return 1; @} @end example @item kill Send a signal. Minimal implementation: @example #include #undef errno extern int errno; int kill(int pid, int sig)@{ errno=EINVAL; return(-1); @} @end example @item link Establish a new name for an existing file. Minimal implementation: @example #include #undef errno extern int errno; int link(char *old, char *new)@{ errno=EMLINK; return -1; @} @end example @item lseek Set position in a file. Minimal implementation: @example int lseek(int file, int ptr, int dir)@{ return 0; @} @end example @item open Open a file. Minimal implementation: @example int open(const char *name, int flags, int mode)@{ return -1; @} @end example @item read Read from a file. Minimal implementation: @example int read(int file, char *ptr, int len)@{ return 0; @} @end example @item sbrk Increase program data space. As @code{malloc} and related functions depend on this, it is useful to have a working implementation. The following suffices for a standalone system; it exploits the symbol @code{end} automatically defined by the GNU linker. @example @group caddr_t sbrk(int incr)@{ extern char end; /* @r{Defined by the linker} */ static char *heap_end; char *prev_heap_end; if (heap_end == 0) @{ heap_end = &end; @} prev_heap_end = heap_end; if (heap_end + incr > stack_ptr) @{ _write (1, "Heap and stack collision\n", 25); abort (); @} heap_end += incr; return (caddr_t) prev_heap_end; @} @end group @end example @item stat Status of a file (by name). Minimal implementation: @example int stat(char *file, struct stat *st) @{ st->st_mode = S_IFCHR; return 0; @} @end example @item times Timing information for current process. Minimal implementation: @example int times(struct tms *buf)@{ return -1; @} @end example @item unlink Remove a file's directory entry. Minimal implementation: @example #include #undef errno extern int errno; int unlink(char *name)@{ errno=ENOENT; return -1; @} @end example @item wait Wait for a child process. Minimal implementation: @example #include #undef errno extern int errno; int wait(int *status) @{ errno=ECHILD; return -1; @} @end example @item write Write a character to a file. @file{libc} subroutines will use this system routine for output to all files, @emph{including} @code{stdout}---so if you need to generate any output, for example to a serial port for debugging, you should make your minimal @code{write} capable of doing this. The following minimal implementation is an incomplete example; it relies on a @code{writechar} subroutine (not shown; typically, you must write this in assembler from examples provided by your hardware manufacturer) to actually perform the output. @example @group int write(int file, char *ptr, int len)@{ int todo; for (todo = 0; todo < len; todo++) @{ writechar(*ptr++); @} return len; @} @end group @end example @end ftable @page @node Reentrant Syscalls @section Reentrant covers for OS subroutines Since the system subroutines are used by other library routines that require reentrancy, @file{libc.a} provides cover routines (for example, the reentrant version of @code{fork} is @code{_fork_r}). These cover routines are consistent with the other reentrant subroutines in this library, and achieve reentrancy by using a reserved global data block (@pxref{Reentrancy,,Reentrancy}). @c FIXME!!! The following ignored text specifies how this section ought @c to work; however, both standalone info and Emacs info mode fail when @c confronted with nodes beginning `_' as of 24may93. Restore when Info @c readers fixed! @ignore @menu * _open_r:: Reentrant version of open * _close_r:: Reentrant version of close * _lseek_r:: Reentrant version of lseek * _read_r:: Reentrant version of read * _write_r:: Reentrant version of write * _link_r:: Reentrant version of link * _unlink_r:: Reentrant version of unlink * _stat_r:: Reentrant version of stat * _fstat_r:: Reentrant version of fstat * _sbrk_r:: Reentrant version of sbrk * _fork_r:: Reentrant version of fork * _wait_r:: Reentrant version of wait @end menu @down @include reent/filer.def @include reent/execr.def @include reent/statr.def @include reent/fstatr.def @include reent/linkr.def @include reent/unlinkr.def @include reent/sbrkr.def @up @end ignore @ftable @code @item _open_r A reentrant version of @code{open}. It takes a pointer to the global data block, which holds @code{errno}. @example int _open_r(void *@var{reent}, const char *@var{file}, int @var{flags}, int @var{mode}); @end example @ifset STDIO64 @item _open64_r A reentrant version of @code{open64}. It takes a pointer to the global data block, which holds @code{errno}. @example int _open64_r(void *@var{reent}, const char *@var{file}, int @var{flags}, int @var{mode}); @end example @end ifset @item _close_r A reentrant version of @code{close}. It takes a pointer to the global data block, which holds @code{errno}. @example int _close_r(void *@var{reent}, int @var{fd}); @end example @item _lseek_r A reentrant version of @code{lseek}. It takes a pointer to the global data block, which holds @code{errno}. @example off_t _lseek_r(void *@var{reent}, int @var{fd}, off_t @var{pos}, int @var{whence}); @end example @ifset STDIO64 @item _lseek64_r A reentrant version of @code{lseek64}. It takes a pointer to the global data block, which holds @code{errno}. @example off_t _lseek64_r(void *@var{reent}, int @var{fd}, off_t @var{pos}, int @var{whence}); @end example @end ifset @item _read_r A reentrant version of @code{read}. It takes a pointer to the global data block, which holds @code{errno}. @example long _read_r(void *@var{reent}, int @var{fd}, void *@var{buf}, size_t @var{cnt}); @end example @item _write_r A reentrant version of @code{write}. It takes a pointer to the global data block, which holds @code{errno}. @example long _write_r(void *@var{reent}, int @var{fd}, const void *@var{buf}, size_t @var{cnt}); @end example @item _fork_r A reentrant version of @code{fork}. It takes a pointer to the global data block, which holds @code{errno}. @example int _fork_r(void *@var{reent}); @end example @item _wait_r A reentrant version of @code{wait}. It takes a pointer to the global data block, which holds @code{errno}. @example int _wait_r(void *@var{reent}, int *@var{status}); @end example @item _stat_r A reentrant version of @code{stat}. It takes a pointer to the global data block, which holds @code{errno}. @example int _stat_r(void *@var{reent}, const char *@var{file}, struct stat *@var{pstat}); @end example @item _fstat_r A reentrant version of @code{fstat}. It takes a pointer to the global data block, which holds @code{errno}. @example int _fstat_r(void *@var{reent}, int @var{fd}, struct stat *@var{pstat}); @end example @ifset STDIO64 @item _fstat64_r A reentrant version of @code{fstat64}. It takes a pointer to the global data block, which holds @code{errno}. @example int _fstat64_r(void *@var{reent}, int @var{fd}, struct stat *@var{pstat}); @end example @end ifset @item _link_r A reentrant version of @code{link}. It takes a pointer to the global data block, which holds @code{errno}. @example int _link_r(void *@var{reent}, const char *@var{old}, const char *@var{new}); @end example @item _unlink_r A reentrant version of @code{unlink}. It takes a pointer to the global data block, which holds @code{errno}. @example int _unlink_r(void *@var{reent}, const char *@var{file}); @end example @item _sbrk_r A reentrant version of @code{sbrk}. It takes a pointer to the global data block, which holds @code{errno}. @example char *_sbrk_r(void *@var{reent}, size_t @var{incr}); @end example @end ftable