|
PROLOG | NAME | SYNOPSIS | DESCRIPTION | RETURN VALUE | ERRORS | EXAMPLES | APPLICATION USAGE | RATIONALE | FUTURE DIRECTIONS | SEE ALSO | COPYRIGHT |
|
EXEC(3P) POSIX Programmer's Manual EXEC(3P)
This manual page is part of the POSIX Programmer's Manual. The Linux
implementation of this interface may differ (consult the
corresponding Linux manual page for details of Linux behavior), or
the interface may not be implemented on Linux.
environ, execl, execle, execlp, execv, execve, execvp, fexecve —
execute a file
#include <unistd.h>
extern char **environ;
int execl(const char *path, const char *arg0, ... /*, (char *)0 */);
int execle(const char *path, const char *arg0, ... /*,
(char *)0, char *const envp[]*/);
int execlp(const char *file, const char *arg0, ... /*, (char *)0 */);
int execv(const char *path, char *const argv[]);
int execve(const char *path, char *const argv[], char *const envp[]);
int execvp(const char *file, char *const argv[]);
int fexecve(int fd, char *const argv[], char *const envp[]);
The exec family of functions shall replace the current process image
with a new process image. The new image shall be constructed from a
regular, executable file called the new process image file. There
shall be no return from a successful exec, because the calling
process image is overlaid by the new process image.
The fexecve() function shall be equivalent to the execve() function
except that the file to be executed is determined by the file
descriptor fd instead of a pathname. The file offset of fd is
ignored.
When a C-language program is executed as a result of a call to one of
the exec family of functions, it shall be entered as a C-language
function call as follows:
int main (int argc, char *argv[]);
where argc is the argument count and argv is an array of character
pointers to the arguments themselves. In addition, the following
variable, which must be declared by the user if it is to be used
directly:
extern char **environ;
is initialized as a pointer to an array of character pointers to the
environment strings. The argv and environ arrays are each terminated
by a null pointer. The null pointer terminating the argv array is not
counted in argc.
Applications can change the entire environment in a single operation
by assigning the environ variable to point to an array of character
pointers to the new environment strings. After assigning a new value
to environ, applications should not rely on the new environment
strings remaining part of the environment, as a call to getenv(),
putenv(), setenv(), unsetenv(), or any function that is dependent on
an environment variable may, on noticing that environ has changed,
copy the environment strings to a new array and assign environ to
point to it.
Any application that directly modifies the pointers to which the
environ variable points has undefined behavior.
Conforming multi-threaded applications shall not use the environ
variable to access or modify any environment variable while any other
thread is concurrently modifying any environment variable. A call to
any function dependent on any environment variable shall be
considered a use of the environ variable to access that environment
variable.
The arguments specified by a program with one of the exec functions
shall be passed on to the new process image in the corresponding
main() arguments.
The argument path points to a pathname that identifies the new
process image file.
The argument file is used to construct a pathname that identifies the
new process image file. If the file argument contains a <slash>
character, the file argument shall be used as the pathname for this
file. Otherwise, the path prefix for this file is obtained by a
search of the directories passed as the environment variable PATH
(see the Base Definitions volume of POSIX.1‐2008, Chapter 8,
Environment Variables). If this environment variable is not present,
the results of the search are implementation-defined.
There are two distinct ways in which the contents of the process
image file may cause the execution to fail, distinguished by the
setting of errno to either [ENOEXEC] or [EINVAL] (see the ERRORS
section). In the cases where the other members of the exec family of
functions would fail and set errno to [ENOEXEC], the execlp() and
execvp() functions shall execute a command interpreter and the
environment of the executed command shall be as if the process
invoked the sh utility using execl() as follows:
execl(<shell path>, arg0, file, arg1, ..., (char *)0);
where <shell path> is an unspecified pathname for the sh utility,
file is the process image file, and for execvp(), where arg0, arg1,
and so on correspond to the values passed to execvp() in argv[0],
argv[1], and so on.
The arguments represented by arg0,... are pointers to null-
terminated character strings. These strings shall constitute the
argument list available to the new process image. The list is
terminated by a null pointer. The argument arg0 should point to a
filename string that is associated with the process being started by
one of the exec functions.
The argument argv is an array of character pointers to null-
terminated strings. The application shall ensure that the last member
of this array is a null pointer. These strings shall constitute the
argument list available to the new process image. The value in
argv[0] should point to a filename string that is associated with the
process being started by one of the exec functions.
The argument envp is an array of character pointers to null-
terminated strings. These strings shall constitute the environment
for the new process image. The envp array is terminated by a null
pointer.
For those forms not containing an envp pointer (execl(), execv(),
execlp(), and execvp()), the environment for the new process image
shall be taken from the external variable environ in the calling
process.
The number of bytes available for the new process' combined argument
and environment lists is {ARG_MAX}. It is implementation-defined
whether null terminators, pointers, and/or any alignment bytes are
included in this total.
File descriptors open in the calling process image shall remain open
in the new process image, except for those whose close-on-exec flag
FD_CLOEXEC is set. For those file descriptors that remain open, all
attributes of the open file description remain unchanged. For any
file descriptor that is closed for this reason, file locks are
removed as a result of the close as described in close(). Locks that
are not removed by closing of file descriptors remain unchanged.
If file descriptor 0, 1, or 2 would otherwise be closed after a
successful call to one of the exec family of functions,
implementations may open an unspecified file for the file descriptor
in the new process image. If a standard utility or a conforming
application is executed with file descriptor 0 not open for reading
or with file descriptor 1 or 2 not open for writing, the environment
in which the utility or application is executed shall be deemed non-
conforming, and consequently the utility or application might not
behave as described in this standard.
Directory streams open in the calling process image shall be closed
in the new process image.
The state of the floating-point environment in the initial thread of
the new process image shall be set to the default.
The state of conversion descriptors and message catalog descriptors
in the new process image is undefined.
For the new process image, the equivalent of:
setlocale(LC_ALL, "C")
shall be executed at start-up.
Signals set to the default action (SIG_DFL) in the calling process
image shall be set to the default action in the new process image.
Except for SIGCHLD, signals set to be ignored (SIG_IGN) by the
calling process image shall be set to be ignored by the new process
image. Signals set to be caught by the calling process image shall be
set to the default action in the new process image (see <signal.h>).
If the SIGCHLD signal is set to be ignored by the calling process
image, it is unspecified whether the SIGCHLD signal is set to be
ignored or to the default action in the new process image.
After a successful call to any of the exec functions, alternate
signal stacks are not preserved and the SA_ONSTACK flag shall be
cleared for all signals.
After a successful call to any of the exec functions, any functions
previously registered by the atexit() or pthread_atfork() functions
are no longer registered.
If the ST_NOSUID bit is set for the file system containing the new
process image file, then the effective user ID, effective group ID,
saved set-user-ID, and saved set-group-ID are unchanged in the new
process image. Otherwise, if the set-user-ID mode bit of the new
process image file is set, the effective user ID of the new process
image shall be set to the user ID of the new process image file.
Similarly, if the set-group-ID mode bit of the new process image file
is set, the effective group ID of the new process image shall be set
to the group ID of the new process image file. The real user ID, real
group ID, and supplementary group IDs of the new process image shall
remain the same as those of the calling process image. The effective
user ID and effective group ID of the new process image shall be
saved (as the saved set-user-ID and the saved set-group-ID) for use
by setuid().
Any shared memory segments attached to the calling process image
shall not be attached to the new process image.
Any named semaphores open in the calling process shall be closed as
if by appropriate calls to sem_close().
Any blocks of typed memory that were mapped in the calling process
are unmapped, as if munmap() was implicitly called to unmap them.
Memory locks established by the calling process via calls to
mlockall() or mlock() shall be removed. If locked pages in the
address space of the calling process are also mapped into the address
spaces of other processes and are locked by those processes, the
locks established by the other processes shall be unaffected by the
call by this process to the exec function. If the exec function
fails, the effect on memory locks is unspecified.
Memory mappings created in the process are unmapped before the
address space is rebuilt for the new process image.
When the calling process image does not use the SCHED_FIFO, SCHED_RR,
or SCHED_SPORADIC scheduling policies, the scheduling policy and
parameters of the new process image and the initial thread in that
new process image are implementation-defined.
When the calling process image uses the SCHED_FIFO, SCHED_RR, or
SCHED_SPORADIC scheduling policies, the process policy and scheduling
parameter settings shall not be changed by a call to an exec
function. The initial thread in the new process image shall inherit
the process scheduling policy and parameters. It shall have the
default system contention scope, but shall inherit its allocation
domain from the calling process image.
Per-process timers created by the calling process shall be deleted
before replacing the current process image with the new process
image.
All open message queue descriptors in the calling process shall be
closed, as described in mq_close().
Any outstanding asynchronous I/O operations may be canceled. Those
asynchronous I/O operations that are not canceled shall complete as
if the exec function had not yet occurred, but any associated signal
notifications shall be suppressed. It is unspecified whether the exec
function itself blocks awaiting such I/O completion. In no event,
however, shall the new process image created by the exec function be
affected by the presence of outstanding asynchronous I/O operations
at the time the exec function is called. Whether any I/O is canceled,
and which I/O may be canceled upon exec, is implementation-defined.
The new process image shall inherit the CPU-time clock of the calling
process image. This inheritance means that the process CPU-time clock
of the process being exec-ed shall not be reinitialized or altered as
a result of the exec function other than to reflect the time spent by
the process executing the exec function itself.
The initial value of the CPU-time clock of the initial thread of the
new process image shall be set to zero.
If the calling process is being traced, the new process image shall
continue to be traced into the same trace stream as the original
process image, but the new process image shall not inherit the
mapping of trace event names to trace event type identifiers that was
defined by calls to the posix_trace_eventid_open() or the
posix_trace_trid_eventid_open() functions in the calling process
image.
If the calling process is a trace controller process, any trace
streams that were created by the calling process shall be shut down
as described in the posix_trace_shutdown() function.
The thread ID of the initial thread in the new process image is
unspecified.
The size and location of the stack on which the initial thread in the
new process image runs is unspecified.
The initial thread in the new process image shall have its
cancellation type set to PTHREAD_CANCEL_DEFERRED and its cancellation
state set to PTHREAD_CANCEL_ENABLED.
The initial thread in the new process image shall have all thread-
specific data values set to NULL and all thread-specific data keys
shall be removed by the call to exec without running destructors.
The initial thread in the new process image shall be joinable, as if
created with the detachstate attribute set to
PTHREAD_CREATE_JOINABLE.
The new process shall inherit at least the following attributes from
the calling process image:
* Nice value (see nice())
* semadj values (see semop())
* Process ID
* Parent process ID
* Process group ID
* Session membership
* Real user ID
* Real group ID
* Supplementary group IDs
* Time left until an alarm clock signal (see alarm())
* Current working directory
* Root directory
* File mode creation mask (see umask())
* File size limit (see getrlimit() and setrlimit())
* Process signal mask (see pthread_sigmask())
* Pending signal (see sigpending())
* tms_utime, tms_stime, tms_cutime, and tms_cstime (see times())
* Resource limits
* Controlling terminal
* Interval timers
The initial thread of the new process shall inherit at least the
following attributes from the calling thread:
* Signal mask (see sigprocmask() and pthread_sigmask())
* Pending signals (see sigpending())
All other process attributes defined in this volume of POSIX.1‐2008
shall be inherited in the new process image from the old process
image. All other thread attributes defined in this volume of
POSIX.1‐2008 shall be inherited in the initial thread in the new
process image from the calling thread in the old process image. The
inheritance of process or thread attributes not defined by this
volume of POSIX.1‐2008 is implementation-defined.
A call to any exec function from a process with more than one thread
shall result in all threads being terminated and the new executable
image being loaded and executed. No destructor functions or cleanup
handlers shall be called.
Upon successful completion, the exec functions shall mark for update
the last data access timestamp of the file. If an exec function
failed but was able to locate the process image file, whether the
last data access timestamp is marked for update is unspecified.
Should the exec function succeed, the process image file shall be
considered to have been opened with open(). The corresponding
close() shall be considered to occur at a time after this open, but
before process termination or successful completion of a subsequent
call to one of the exec functions, posix_spawn(), or posix_spawnp().
The argv[] and envp[] arrays of pointers and the strings to which
those arrays point shall not be modified by a call to one of the exec
functions, except as a consequence of replacing the process image.
The saved resource limits in the new process image are set to be a
copy of the process' corresponding hard and soft limits.
If one of the exec functions returns to the calling process image, an
error has occurred; the return value shall be −1, and errno shall be
set to indicate the error.
The exec functions shall fail if:
E2BIG The number of bytes used by the new process image's argument
list and environment list is greater than the system-imposed
limit of {ARG_MAX} bytes.
EACCES The new process image file is not a regular file and the
implementation does not support execution of files of its
type.
EINVAL The new process image file has appropriate privileges and has
a recognized executable binary format, but the system does not
support execution of a file with this format.
The exec functions, except for fexecve(), shall fail if:
EACCES Search permission is denied for a directory listed in the new
process image file's path prefix, or the new process image
file denies execution permission.
ELOOP A loop exists in symbolic links encountered during resolution
of the path or file argument.
ENAMETOOLONG
The length of a component of a pathname is longer than
{NAME_MAX}.
ENOENT A component of path or file does not name an existing file or
path or file is an empty string.
ENOTDIR
A component of the new process image file's path prefix names
an existing file that is neither a directory nor a symbolic
link to a directory, or the new process image file's pathname
contains at least one non-<slash> character and ends with one
or more trailing <slash> characters and the last pathname
component names an existing file that is neither a directory
nor a symbolic link to a directory.
The exec functions, except for execlp() and execvp(), shall fail if:
ENOEXEC
The new process image file has the appropriate access
permission but has an unrecognized format.
The fexecve() function shall fail if:
EBADF The fd argument is not a valid file descriptor open for
executing.
The exec functions may fail if:
ENOMEM The new process image requires more memory than is allowed by
the hardware or system-imposed memory management constraints.
The exec functions, except for fexecve(), may fail if:
ELOOP More than {SYMLOOP_MAX} symbolic links were encountered during
resolution of the path or file argument.
ENAMETOOLONG
The length of the path argument or the length of the pathname
constructed from the file argument exceeds {PATH_MAX}, or
pathname resolution of a symbolic link produced an
intermediate result with a length that exceeds {PATH_MAX}.
ETXTBSY
The new process image file is a pure procedure (shared text)
file that is currently open for writing by some process.
The following sections are informative.
Using execl()
The following example executes the ls command, specifying the
pathname of the executable (/bin/ls) and using arguments supplied
directly to the command to produce single-column output.
#include <unistd.h>
int ret;
...
ret = execl ("/bin/ls", "ls", "-1", (char *)0);
Using execle()
The following example is similar to Using execl(). In addition, it
specifies the environment for the new process image using the env
argument.
#include <unistd.h>
int ret;
char *env[] = { "HOME=/usr/home", "LOGNAME=home", (char *)0 };
...
ret = execle ("/bin/ls", "ls", "-l", (char *)0, env);
Using execlp()
The following example searches for the location of the ls command
among the directories specified by the PATH environment variable.
#include <unistd.h>
int ret;
...
ret = execlp ("ls", "ls", "-l", (char *)0);
Using execv()
The following example passes arguments to the ls command in the cmd
array.
#include <unistd.h>
int ret;
char *cmd[] = { "ls", "-l", (char *)0 };
...
ret = execv ("/bin/ls", cmd);
Using execve()
The following example passes arguments to the ls command in the cmd
array, and specifies the environment for the new process image using
the env argument.
#include <unistd.h>
int ret;
char *cmd[] = { "ls", "-l", (char *)0 };
char *env[] = { "HOME=/usr/home", "LOGNAME=home", (char *)0 };
...
ret = execve ("/bin/ls", cmd, env);
Using execvp()
The following example searches for the location of the ls command
among the directories specified by the PATH environment variable, and
passes arguments to the ls command in the cmd array.
#include <unistd.h>
int ret;
char *cmd[] = { "ls", "-l", (char *)0 };
...
ret = execvp ("ls", cmd);
As the state of conversion descriptors and message catalog
descriptors in the new process image is undefined, conforming
applications should not rely on their use and should close them prior
to calling one of the exec functions.
Applications that require other than the default POSIX locale as the
global locale in the new process image should call setlocale() with
the appropriate parameters.
When assigning a new value to the environ variable, applications
should ensure that the environment to which it will point contains at
least the following:
1. Any implementation-defined variables required by the
implementation to provide a conforming environment. See the
_CS_V7_ENV entry in <unistd.h> and confstr() for details.
2. A value for PATH which finds conforming versions of all standard
utilities before any other versions.
The same constraint applies to the envp array passed to execle() or
execve(), in order to ensure that the new process image is invoked in
a conforming environment.
Applications should not execute programs with file descriptor 0 not
open for reading or with file descriptor 1 or 2 not open for writing,
as this might cause the executed program to misbehave. In order not
to pass on these file descriptors to an executed program,
applications should not just close them but should reopen them on,
for example, /dev/null. Some implementations may reopen them
automatically, but applications should not rely on this being done.
If an application wants to perform a checksum test of the file being
executed before executing it, the file will need to be opened with
read permission to perform the checksum test.
Since execute permission is checked by fexecve(), the file
description fd need not have been opened with the O_EXEC flag.
However, if the file to be executed denies read and write permission
for the process preparing to do the exec, the only way to provide the
fd to fexecve() will be to use the O_EXEC flag when opening fd. In
this case, the application will not be able to perform a checksum
test since it will not be able to read the contents of the file.
Note that when a file descriptor is opened with O_RDONLY, O_RDWR, or
O_WRONLY mode, the file descriptor can be used to read, read and
write, or write the file, respectively, even if the mode of the file
changes after the file was opened. Using the O_EXEC open mode is
different; fexecve() will ignore the mode that was used when the file
descriptor was opened and the exec will fail if the mode of the file
associated with fd does not grant execute permission to the calling
process at the time fexecve() is called.
Early proposals required that the value of argc passed to main() be
``one or greater''. This was driven by the same requirement in drafts
of the ISO C standard. In fact, historical implementations have
passed a value of zero when no arguments are supplied to the caller
of the exec functions. This requirement was removed from the ISO C
standard and subsequently removed from this volume of POSIX.1‐2008 as
well. The wording, in particular the use of the word should, requires
a Strictly Conforming POSIX Application to pass at least one argument
to the exec function, thus guaranteeing that argc be one or greater
when invoked by such an application. In fact, this is good practice,
since many existing applications reference argv[0] without first
checking the value of argc.
The requirement on a Strictly Conforming POSIX Application also
states that the value passed as the first argument be a filename
string associated with the process being started. Although some
existing applications pass a pathname rather than a filename string
in some circumstances, a filename string is more generally useful,
since the common usage of argv[0] is in printing diagnostics. In some
cases the filename passed is not the actual filename of the file; for
example, many implementations of the login utility use a convention
of prefixing a <hyphen> ('‐') to the actual filename, which indicates
to the command interpreter being invoked that it is a ``login
shell''.
Historically, there have been two ways that implementations can exec
shell scripts.
One common historical implementation is that the execl(), execv(),
execle(), and execve() functions return an [ENOEXEC] error for any
file not recognizable as executable, including a shell script. When
the execlp() and execvp() functions encounter such a file, they
assume the file to be a shell script and invoke a known command
interpreter to interpret such files. This is now required by
POSIX.1‐2008. These implementations of execvp() and execlp() only
give the [ENOEXEC] error in the rare case of a problem with the
command interpreter's executable file. Because of these
implementations, the [ENOEXEC] error is not mentioned for execlp() or
execvp(), although implementations can still give it.
Another way that some historical implementations handle shell scripts
is by recognizing the first two bytes of the file as the character
string "#!" and using the remainder of the first line of the file as
the name of the command interpreter to execute.
One potential source of confusion noted by the standard developers is
over how the contents of a process image file affect the behavior of
the exec family of functions. The following is a description of the
actions taken:
1. If the process image file is a valid executable (in a format that
is executable and valid and having appropriate privileges) for
this system, then the system executes the file.
2. If the process image file has appropriate privileges and is in a
format that is executable but not valid for this system (such as
a recognized binary for another architecture), then this is an
error and errno is set to [EINVAL] (see later RATIONALE on
[EINVAL]).
3. If the process image file has appropriate privileges but is not
otherwise recognized:
a. If this is a call to execlp() or execvp(), then they invoke a
command interpreter assuming that the process image file is a
shell script.
b. If this is not a call to execlp() or execvp(), then an error
occurs and errno is set to [ENOEXEC].
Applications that do not require to access their arguments may use
the form:
main(void)
as specified in the ISO C standard. However, the implementation will
always provide the two arguments argc and argv, even if they are not
used.
Some implementations provide a third argument to main() called envp.
This is defined as a pointer to the environment. The ISO C standard
specifies invoking main() with two arguments, so implementations must
support applications written this way. Since this volume of
POSIX.1‐2008 defines the global variable environ, which is also
provided by historical implementations and can be used anywhere that
envp could be used, there is no functional need for the envp
argument. Applications should use the getenv() function rather than
accessing the environment directly via either envp or environ.
Implementations are required to support the two-argument calling
sequence, but this does not prohibit an implementation from
supporting envp as an optional third argument.
This volume of POSIX.1‐2008 specifies that signals set to SIG_IGN
remain set to SIG_IGN, and that the new process image inherits the
signal mask of the thread that called exec in the old process image.
This is consistent with historical implementations, and it permits
some useful functionality, such as the nohup command. However, it
should be noted that many existing applications wrongly assume that
they start with certain signals set to the default action and/or
unblocked. In particular, applications written with a simpler signal
model that does not include blocking of signals, such as the one in
the ISO C standard, may not behave properly if invoked with some
signals blocked. Therefore, it is best not to block or ignore signals
across execs without explicit reason to do so, and especially not to
block signals across execs of arbitrary (not closely cooperating)
programs.
The exec functions always save the value of the effective user ID and
effective group ID of the process at the completion of the exec,
whether or not the set-user-ID or the set-group-ID bit of the process
image file is set.
The statement about argv[] and envp[] being constants is included to
make explicit to future writers of language bindings that these
objects are completely constant. Due to a limitation of the ISO C
standard, it is not possible to state that idea in standard C.
Specifying two levels of const−qualification for the argv[] and
envp[] parameters for the exec functions may seem to be the natural
choice, given that these functions do not modify either the array of
pointers or the characters to which the function points, but this
would disallow existing correct code. Instead, only the array of
pointers is noted as constant. The table of assignment compatibility
for dst=src derived from the ISO C standard summarizes the
compatibility:
┌────────────────────┬──────────┬────────────────┬───────────────┬─────────────────────┐
│ dst: │ char *[] │ const char *[] │ char *const[] │ const char *const[] │
├────────────────────┼──────────┼────────────────┼───────────────┼─────────────────────┤
│src: │ │ │ │ │
│char *[] │ VALID │ — │ VALID │ — │
│const char *[] │ — │ VALID │ — │ VALID │
│char * const [] │ — │ — │ VALID │ — │
│const char *const[] │ — │ — │ — │ VALID │
└────────────────────┴──────────┴────────────────┴───────────────┴─────────────────────┘
Since all existing code has a source type matching the first row, the
column that gives the most valid combinations is the third column.
The only other possibility is the fourth column, but using it would
require a cast on the argv or envp arguments. It is unfortunate that
the fourth column cannot be used, because the declaration a non-
expert would naturally use would be that in the second row.
The ISO C standard and this volume of POSIX.1‐2008 do not conflict on
the use of environ, but some historical implementations of environ
may cause a conflict. As long as environ is treated in the same way
as an entry point (for example, fork()), it conforms to both
standards. A library can contain fork(), but if there is a user-
provided fork(), that fork() is given precedence and no problem
ensues. The situation is similar for environ: the definition in this
volume of POSIX.1‐2008 is to be used if there is no user-provided
environ to take precedence. At least three implementations are known
to exist that solve this problem.
E2BIG The limit {ARG_MAX} applies not just to the size of the
argument list, but to the sum of that and the size of the
environment list.
EFAULT Some historical systems return [EFAULT] rather than [ENOEXEC]
when the new process image file is corrupted. They are non-
conforming.
EINVAL This error condition was added to POSIX.1‐2008 to allow an
implementation to detect executable files generated for
different architectures, and indicate this situation to the
application. Historical implementations of shells, execvp(),
and execlp() that encounter an [ENOEXEC] error will execute a
shell on the assumption that the file is a shell script. This
will not produce the desired effect when the file is a valid
executable for a different architecture. An implementation may
now choose to avoid this problem by returning [EINVAL] when a
valid executable for a different architecture is encountered.
Some historical implementations return [EINVAL] to indicate
that the path argument contains a character with the high
order bit set. The standard developers chose to deviate from
historical practice for the following reasons:
1. The new utilization of [EINVAL] will provide some
measure of utility to the user community.
2. Historical use of [EINVAL] is not acceptable in an
internationalized operating environment.
ENAMETOOLONG
Since the file pathname may be constructed by taking elements
in the PATH variable and putting them together with the
filename, the [ENAMETOOLONG] error condition could also be
reached this way.
ETXTBSY
System V returns this error when the executable file is
currently open for writing by some process. This volume of
POSIX.1‐2008 neither requires nor prohibits this behavior.
Other systems (such as System V) may return [EINTR] from exec. This
is not addressed by this volume of POSIX.1‐2008, but implementations
may have a window between the call to exec and the time that a signal
could cause one of the exec calls to return with [EINTR].
An explicit statement regarding the floating-point environment (as
defined in the <fenv.h> header) was added to make it clear that the
floating-point environment is set to its default when a call to one
of the exec functions succeeds. The requirements for inheritance or
setting to the default for other process and thread start-up
functions is covered by more generic statements in their descriptions
and can be summarized as follows:
posix_spawn (3p) 14
Set to default.
fork (3p) 14
Inherit.
pthread_create (3p) 14
Inherit.
The purpose of the fexecve() function is to enable executing a file
which has been verified to be the intended file. It is possible to
actively check the file by reading from the file descriptor and be
sure that the file is not exchanged for another between the reading
and the execution. Alternatively, an function like openat() can be
used to open a file which has been found by reading the content of a
directory using readdir().
None.
alarm(3p), atexit(3p), chmod(3p), close(3p), confstr(3p), exit(3p),
fcntl(3p), fork(3p), fstatvfs(3p), getenv(3p), getitimer(3p),
getrlimit(3p), mknod(3p), mmap(3p), nice(3p), open(3p),
posix_spawn(3p), posix_trace_create(3p), posix_trace_event(3p),
posix_trace_eventid_equal(3p), pthread_atfork(3p),
pthread_sigmask(3p), putenv(3p), readdir(3p), semop(3p),
setlocale(3p), shmat(3p), sigaction(3p), sigaltstack(3p),
sigpending(3p), system(3p), times(3p), ulimit(3p), umask(3p)
The Base Definitions volume of POSIX.1‐2008, Chapter 8, Environment
Variables, unistd.h(0p)
Portions of this text are reprinted and reproduced in electronic form
from IEEE Std 1003.1, 2013 Edition, Standard for Information
Technology -- Portable Operating System Interface (POSIX), The Open
Group Base Specifications Issue 7, Copyright (C) 2013 by the
Institute of Electrical and Electronics Engineers, Inc and The Open
Group. (This is POSIX.1-2008 with the 2013 Technical Corrigendum 1
applied.) In the event of any discrepancy between this version and
the original IEEE and The Open Group Standard, the original IEEE and
The Open Group Standard is the referee document. The original
Standard can be obtained online at http://www.unix.org/online.html .
Any typographical or formatting errors that appear in this page are
most likely to have been introduced during the conversion of the
source files to man page format. To report such errors, see
https://www.kernel.org/doc/man-pages/reporting_bugs.html .
IEEE/The Open Group 2013 EXEC(3P)
|
HTML rendering created 2018-02-02 by Michael Kerrisk, author of The Linux Programming Interface, maintainer of the Linux man-pages project. For details of in-depth Linux/UNIX system programming training courses that I teach, look here. Hosting by jambit GmbH.
|
|