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/** \file postfork.cpp
Functions that we may safely call after fork ( ) .
*/
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# include <fcntl.h>
# include "signal.h"
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# include "postfork.h"
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# include "iothread.h"
# include "exec.h"
/** The number of times to try to call fork() before giving up */
# define FORK_LAPS 5
/** The number of nanoseconds to sleep between attempts to call fork() */
# define FORK_SLEEP_TIME 1000000
/** Base open mode to pass to calls to open */
# define OPEN_MASK 0666
/** fork error message */
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# define FORK_ERROR "Could not create child process - exiting"
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/** file redirection clobbering error message */
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# define NOCLOB_ERROR "The file '%s' already exists"
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/** file redirection error message */
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# define FILE_ERROR "An error occurred while redirecting file '%s'"
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/** file descriptor redirection error message */
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# define FD_ERROR "An error occurred while redirecting file descriptor %s"
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/** pipe error */
# define LOCAL_PIPE_ERROR "An error occurred while setting up pipe"
/* Cover for debug_safe that can take an int. The format string should expect a %s */
static void debug_safe_int ( int level , const char * format , int val )
{
char buff [ 128 ] ;
format_long_safe ( buff , val ) ;
debug_safe ( level , format , buff ) ;
}
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// PCA These calls to debug are rather sketchy because they may allocate memory. Fortunately they only occur if an error occurs.
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int set_child_group ( job_t * j , process_t * p , int print_errors )
{
int res = 0 ;
if ( job_get_flag ( j , JOB_CONTROL ) )
{
if ( ! j - > pgid )
{
j - > pgid = p - > pid ;
}
if ( setpgid ( p - > pid , j - > pgid ) )
{
if ( getpgid ( p - > pid ) ! = j - > pgid & & print_errors )
{
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char pid_buff [ 128 ] ;
char job_id_buff [ 128 ] ;
char getpgid_buff [ 128 ] ;
char job_pgid_buff [ 128 ] ;
format_long_safe ( pid_buff , p - > pid ) ;
format_long_safe ( job_id_buff , j - > job_id ) ;
format_long_safe ( getpgid_buff , getpgid ( p - > pid ) ) ;
format_long_safe ( job_pgid_buff , j - > pgid ) ;
debug_safe ( 1 ,
" Could not send process %s, '%s' in job %s, '%s' from group %s to group %s " ,
pid_buff ,
p - > argv0_cstr ( ) ,
job_id_buff ,
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j - > command_cstr ( ) ,
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getpgid_buff ,
job_pgid_buff ) ;
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wperror ( L " setpgid " ) ;
res = - 1 ;
}
}
}
else
{
j - > pgid = getpid ( ) ;
}
if ( job_get_flag ( j , JOB_TERMINAL ) & & job_get_flag ( j , JOB_FOREGROUND ) )
{
if ( tcsetpgrp ( 0 , j - > pgid ) & & print_errors )
{
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char job_id_buff [ 128 ] ;
format_long_safe ( job_id_buff , j - > job_id ) ;
debug_safe ( 1 , " Could not send job %s ('%s') to foreground " , job_id_buff , j - > command_cstr ( ) ) ;
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wperror ( L " tcsetpgrp " ) ;
res = - 1 ;
}
}
return res ;
}
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/** Make sure the fd used by each redirection is not used by a pipe. */
static void free_redirected_fds_from_pipes ( io_chain_t & io_chain )
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{
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size_t max = io_chain . size ( ) ;
for ( size_t i = 0 ; i < max ; i + + )
{
int fd_to_free = io_chain . at ( i ) - > fd ;
/* We only have to worry about fds beyond the three standard ones */
if ( fd_to_free < = 2 )
continue ;
/* Make sure the fd is not used by a pipe */
for ( size_t j = 0 ; j < max ; j + + )
{
/* We're only interested in pipes */
io_data_t * possible_conflict = io_chain . at ( j ) ;
if ( possible_conflict - > io_mode ! = IO_PIPE & & possible_conflict - > io_mode ! = IO_BUFFER )
continue ;
/* If the pipe is a conflict, dup it to some other value */
for ( int k = 0 ; k < 2 ; k + + )
{
/* If it's not a conflict, we don't care */
if ( possible_conflict - > param1 . pipe_fd [ k ] ! = fd_to_free )
continue ;
/* Repeat until we have a replacement fd */
int replacement_fd = - 1 ;
while ( replacement_fd < 0 )
{
replacement_fd = dup ( fd_to_free ) ;
if ( replacement_fd = = - 1 & & errno ! = EINTR )
{
debug_safe_int ( 1 , FD_ERROR , fd_to_free ) ;
wperror ( L " dup " ) ;
FATAL_EXIT ( ) ;
}
}
possible_conflict - > param1 . pipe_fd [ k ] = replacement_fd ;
}
}
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}
}
/**
Set up a childs io redirections . Should only be called by
setup_child_process ( ) . Does the following : First it closes any open
file descriptors not related to the child by calling
close_unused_internal_pipes ( ) and closing the universal variable
server file descriptor . It then goes on to perform all the
redirections described by \ c io .
\ param io the list of IO redirections for the child
\ return 0 on sucess , - 1 on failiure
*/
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static int handle_child_io ( io_chain_t & io_chain )
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{
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close_unused_internal_pipes ( io_chain ) ;
free_redirected_fds_from_pipes ( io_chain ) ;
for ( size_t idx = 0 ; idx < io_chain . size ( ) ; idx + + )
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{
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io_data_t * io = io_chain . at ( idx ) ;
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int tmp ;
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if ( io - > io_mode = = IO_FD & & io - > fd = = io - > param1 . old_fd )
{
continue ;
}
switch ( io - > io_mode )
{
case IO_CLOSE :
{
if ( close ( io - > fd ) )
{
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debug_safe_int ( 0 , " Failed to close file descriptor %s " , io - > fd ) ;
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wperror ( L " close " ) ;
}
break ;
}
case IO_FILE :
{
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// Here we definitely do not want to set CLO_EXEC because our child needs access
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if ( ( tmp = open ( io - > filename_cstr ,
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io - > param2 . flags , OPEN_MASK ) ) = = - 1 )
{
if ( ( io - > param2 . flags & O_EXCL ) & &
( errno = = EEXIST ) )
{
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debug_safe ( 1 , NOCLOB_ERROR , io - > filename_cstr ) ;
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}
else
{
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debug_safe ( 1 , FILE_ERROR , io - > filename_cstr ) ;
perror ( " open " ) ;
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}
return - 1 ;
}
else if ( tmp ! = io - > fd )
{
/*
This call will sometimes fail , but that is ok ,
this is just a precausion .
*/
close ( io - > fd ) ;
if ( dup2 ( tmp , io - > fd ) = = - 1 )
{
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debug_safe_int ( 1 , FD_ERROR , io - > fd ) ;
perror ( " dup2 " ) ;
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return - 1 ;
}
exec_close ( tmp ) ;
}
break ;
}
case IO_FD :
{
/*
This call will sometimes fail , but that is ok ,
this is just a precausion .
*/
close ( io - > fd ) ;
if ( dup2 ( io - > param1 . old_fd , io - > fd ) = = - 1 )
{
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debug_safe_int ( 1 , FD_ERROR , io - > fd ) ;
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wperror ( L " dup2 " ) ;
return - 1 ;
}
break ;
}
case IO_BUFFER :
case IO_PIPE :
{
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/* If write_pipe_idx is 0, it means we're connecting to the read end (first pipe fd). If it's 1, we're connecting to the write end (second pipe fd). */
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unsigned int write_pipe_idx = ( io - > is_input ? 0 : 1 ) ;
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/*
debug ( 0 ,
L " %ls %ls on fd %d (%d %d) " ,
write_pipe ? L " write " : L " read " ,
( io - > io_mode = = IO_BUFFER ) ? L " buffer " : L " pipe " ,
io - > fd ,
io - > param1 . pipe_fd [ 0 ] ,
io - > param1 . pipe_fd [ 1 ] ) ;
*/
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if ( dup2 ( io - > param1 . pipe_fd [ write_pipe_idx ] , io - > fd ) ! = io - > fd )
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{
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debug_safe ( 1 , LOCAL_PIPE_ERROR ) ;
perror ( " dup2 " ) ;
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return - 1 ;
}
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if ( io - > param1 . pipe_fd [ 0 ] > = 0 )
exec_close ( io - > param1 . pipe_fd [ 0 ] ) ;
if ( io - > param1 . pipe_fd [ 1 ] > = 0 )
exec_close ( io - > param1 . pipe_fd [ 1 ] ) ;
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break ;
}
}
}
return 0 ;
}
int setup_child_process ( job_t * j , process_t * p )
{
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bool ok = true ;
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if ( p )
{
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ok = ( 0 = = set_child_group ( j , p , 1 ) ) ;
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}
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if ( ok )
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{
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ok = ( 0 = = handle_child_io ( j - > io ) ) ;
if ( p ! = 0 & & ! ok )
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{
exit_without_destructors ( 1 ) ;
}
}
/* Set the handling for job control signals back to the default. */
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if ( ok )
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{
signal_reset_handlers ( ) ;
}
/* Remove all signal blocks */
signal_unblock ( ) ;
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return ok ? 0 : - 1 ;
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}
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int g_fork_count = 0 ;
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/**
This function is a wrapper around fork . If the fork calls fails
with EAGAIN , it is retried FORK_LAPS times , with a very slight
delay between each lap . If fork fails even then , the process will
exit with an error message .
*/
pid_t execute_fork ( bool wait_for_threads_to_die )
{
ASSERT_IS_MAIN_THREAD ( ) ;
if ( wait_for_threads_to_die ) {
/* Make sure we have no outstanding threads before we fork. This is a pretty sketchy thing to do here, both because exec.cpp shouldn't have to know about iothreads, and because the completion handlers may do unexpected things. */
iothread_drain_all ( ) ;
}
pid_t pid ;
struct timespec pollint ;
int i ;
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g_fork_count + + ;
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for ( i = 0 ; i < FORK_LAPS ; i + + )
{
pid = fork ( ) ;
if ( pid > = 0 )
{
return pid ;
}
if ( errno ! = EAGAIN )
{
break ;
}
pollint . tv_sec = 0 ;
pollint . tv_nsec = FORK_SLEEP_TIME ;
/*
Don ' t sleep on the final lap - sleeping might change the
value of errno , which will break the error reporting below .
*/
if ( i ! = FORK_LAPS - 1 )
{
nanosleep ( & pollint , NULL ) ;
}
}
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debug_safe ( 0 , FORK_ERROR ) ;
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wperror ( L " fork " ) ;
FATAL_EXIT ( ) ;
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return 0 ;
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}
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# if FISH_USE_POSIX_SPAWN
bool fork_actions_make_spawn_properties ( posix_spawnattr_t * attr , posix_spawn_file_actions_t * actions , job_t * j , process_t * p )
{
/* Initialize the output */
if ( posix_spawnattr_init ( attr ) ! = 0 ) {
return false ;
}
if ( posix_spawn_file_actions_init ( actions ) ! = 0 ) {
posix_spawnattr_destroy ( attr ) ;
return false ;
}
bool should_set_parent_group_id = false ;
int desired_parent_group_id = 0 ;
if ( job_get_flag ( j , JOB_CONTROL ) )
{
should_set_parent_group_id = true ;
// PCA: I'm quite fuzzy on process groups,
// but I believe that the default value of 0
// means that the process becomes its own
// group leader, which is what set_child_group did
// in this case. So we want this to be 0 if j->pgid is 0.
desired_parent_group_id = j - > pgid ;
}
/* Set the handling for job control signals back to the default. */
bool reset_signal_handlers = true ;
/* Remove all signal blocks */
bool reset_sigmask = true ;
/* Set our flags */
short flags = 0 ;
if ( reset_signal_handlers )
flags | = POSIX_SPAWN_SETSIGDEF ;
if ( reset_sigmask )
flags | = POSIX_SPAWN_SETSIGMASK ;
if ( should_set_parent_group_id )
flags | = POSIX_SPAWN_SETPGROUP ;
int err = 0 ;
if ( ! err )
err = posix_spawnattr_setflags ( attr , flags ) ;
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if ( ! err & & should_set_parent_group_id )
err = posix_spawnattr_setpgroup ( attr , desired_parent_group_id ) ;
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/* Everybody gets default handlers */
if ( ! err & & reset_signal_handlers )
{
sigset_t sigdefault ;
get_signals_with_handlers ( & sigdefault ) ;
err = posix_spawnattr_setsigdefault ( attr , & sigdefault ) ;
}
/* No signals blocked */
sigset_t sigmask ;
sigemptyset ( & sigmask ) ;
if ( ! err & & reset_sigmask )
err = posix_spawnattr_setsigmask ( attr , & sigmask ) ;
/* Make sure that our pipes don't use an fd that the redirection itself wants to use */
free_redirected_fds_from_pipes ( j - > io ) ;
/* Close unused internal pipes */
std : : vector < int > files_to_close ;
get_unused_internal_pipes ( files_to_close , j - > io ) ;
for ( size_t i = 0 ; ! err & & i < files_to_close . size ( ) ; i + + )
{
err = posix_spawn_file_actions_addclose ( actions , files_to_close . at ( i ) ) ;
}
for ( size_t idx = 0 ; idx < j - > io . size ( ) ; idx + + )
{
const io_data_t * io = j - > io . at ( idx ) ;
if ( io - > io_mode = = IO_FD & & io - > fd = = io - > param1 . old_fd )
{
continue ;
}
if ( io - > fd > 2 )
{
/* Make sure the fd used by this redirection is not used by e.g. a pipe. */
// free_fd(io_chain, io->fd );
// PCA I don't think we need to worry about this. fd redirection is pretty uncommon anyways.
}
switch ( io - > io_mode )
{
case IO_CLOSE :
{
if ( ! err )
err = posix_spawn_file_actions_addclose ( actions , io - > fd ) ;
break ;
}
case IO_FILE :
{
if ( ! err )
err = posix_spawn_file_actions_addopen ( actions , io - > fd , io - > filename_cstr , io - > param2 . flags /* mode */ , OPEN_MASK ) ;
break ;
}
case IO_FD :
{
if ( ! err )
err = posix_spawn_file_actions_adddup2 ( actions , io - > param1 . old_fd /* from */ , io - > fd /* to */ ) ;
break ;
}
case IO_BUFFER :
case IO_PIPE :
{
unsigned int write_pipe_idx = ( io - > is_input ? 0 : 1 ) ;
int from_fd = io - > param1 . pipe_fd [ write_pipe_idx ] ;
int to_fd = io - > fd ;
if ( ! err )
err = posix_spawn_file_actions_adddup2 ( actions , from_fd , to_fd ) ;
if ( write_pipe_idx > 0 )
{
if ( ! err )
err = posix_spawn_file_actions_addclose ( actions , io - > param1 . pipe_fd [ 0 ] ) ;
if ( ! err )
err = posix_spawn_file_actions_addclose ( actions , io - > param1 . pipe_fd [ 1 ] ) ;
}
else
{
if ( ! err )
err = posix_spawn_file_actions_addclose ( actions , io - > param1 . pipe_fd [ 0 ] ) ;
}
break ;
}
}
}
/* Clean up on error */
if ( err ) {
posix_spawnattr_destroy ( attr ) ;
posix_spawn_file_actions_destroy ( actions ) ;
}
return ! err ;
}
# endif //FISH_USE_POSIX_SPAWN
void safe_report_exec_error ( int err , const char * actual_cmd , char * * argv , char * * envv )
{
debug_safe ( 0 , " Failed to execute process '%s'. Reason: " , actual_cmd ) ;
switch ( err )
{
case E2BIG :
{
char sz1 [ 128 ] , sz2 [ 128 ] ;
long arg_max = - 1 ;
size_t sz = 0 ;
char * * p ;
for ( p = argv ; * p ; p + + )
{
sz + = strlen ( * p ) + 1 ;
}
for ( p = envv ; * p ; p + + )
{
sz + = strlen ( * p ) + 1 ;
}
format_size_safe ( sz1 , sz ) ;
arg_max = sysconf ( _SC_ARG_MAX ) ;
if ( arg_max > 0 )
{
format_size_safe ( sz2 , sz ) ;
debug_safe ( 0 , " The total size of the argument and environment lists %s exceeds the operating system limit of %s. " , sz1 , sz2 ) ;
}
else
{
debug_safe ( 0 , " The total size of the argument and environment lists (%s) exceeds the operating system limit. " , sz1 ) ;
}
debug_safe ( 0 , " Try running the command again with fewer arguments. " ) ;
break ;
}
case ENOEXEC :
{
/* Hope strerror doesn't allocate... */
const char * err = strerror ( errno ) ;
debug_safe ( 0 , " exec: %s " , err ) ;
debug_safe ( 0 , " The file '%s' is marked as an executable but could not be run by the operating system. " , actual_cmd ) ;
break ;
}
case ENOENT :
{
char interpreter_buff [ 128 ] = { } , * interpreter ;
interpreter = get_interpreter ( actual_cmd , interpreter_buff , sizeof interpreter_buff ) ;
if ( interpreter & & 0 ! = access ( interpreter , X_OK ) )
{
debug_safe ( 0 , " The file '%s' specified the interpreter '%s', which is not an executable command. " , actual_cmd , interpreter ) ;
}
else
{
debug_safe ( 0 , " The file '%s' or a script or ELF interpreter does not exist, or a shared library needed for file or interpreter cannot be found. " , actual_cmd ) ;
}
break ;
}
case ENOMEM :
{
debug_safe ( 0 , " Out of memory " ) ;
break ;
}
default :
{
/* Hope strerror doesn't allocate... */
const char * err = strerror ( errno ) ;
debug_safe ( 0 , " exec: %s " , err ) ;
// debug(0, L"The file '%ls' is marked as an executable but could not be run by the operating system.", p->actual_cmd);
break ;
}
}
}