man2/sigaltstack.2 - pub/scm/docs/man-pages/man-pages - Git at Google

 .\" Copyright (c) 2001, 2017 Michael Kerrisk <mtk.manpages@gmail.com>
 .\"
 .\" %%%LICENSE_START(VERBATIM)
 .\" Permission is granted to make and distribute verbatim copies of this
 .\" manual provided the copyright notice and this permission notice are
 .\" preserved on all copies.
 .\"
 .\" Permission is granted to copy and distribute modified versions of this
 .\" manual under the conditions for verbatim copying, provided that the
 .\" entire resulting derived work is distributed under the terms of a
 .\" permission notice identical to this one.
 .\"
 .\" Since the Linux kernel and libraries are constantly changing, this
 .\" manual page may be incorrect or out-of-date.  The author(s) assume no
 .\" responsibility for errors or omissions, or for damages resulting from
 .\" the use of the information contained herein.  The author(s) may not
 .\" have taken the same level of care in the production of this manual,
 .\" which is licensed free of charge, as they might when working
 .\" professionally.
 .\"
 .\" Formatted or processed versions of this manual, if unaccompanied by
 .\" the source, must acknowledge the copyright and authors of this work.
 .\" %%%LICENSE_END
 .\"
 .\" aeb, various minor fixes
 .TH SIGALTSTACK 2 2021-03-22 "Linux" "Linux Programmer's Manual"
 .SH NAME
 sigaltstack \- set and/or get signal stack context
 .SH SYNOPSIS
 .nf
 .B #include <signal.h>
 .PP
 .BI "int sigaltstack(const stack_t *restrict " ss \
 ", stack_t *restrict " old_ss );
 .fi
 .PP
 .RS -4
 Feature Test Macro Requirements for glibc (see
 .BR feature_test_macros (7)):
 .RE
 .PP
 .BR sigaltstack ():
 .nf
     _XOPEN_SOURCE >= 500
 .\"    || _XOPEN_SOURCE && _XOPEN_SOURCE_EXTENDED
         || /* Since glibc 2.12: */ _POSIX_C_SOURCE >= 200809L
         || /* Glibc <= 2.19: */ _BSD_SOURCE
 .fi
 .SH DESCRIPTION
 .BR sigaltstack ()
 allows a thread to define a new alternate
 signal stack and/or retrieve the state of an existing
 alternate signal stack.
 An alternate signal stack is used during the
 execution of a signal handler if the establishment of that handler (see
 .BR sigaction (2))
 requested it.
 .PP
 The normal sequence of events for using an alternate signal stack
 is the following:
 .TP 3
 1.
 Allocate an area of memory to be used for the alternate
 signal stack.
 .TP
 2.
 Use
 .BR sigaltstack ()
 to inform the system of the existence and
 location of the alternate signal stack.
 .TP
 3.
 When establishing a signal handler using
 .BR sigaction (2),
 inform the system that the signal handler should be executed
 on the alternate signal stack by
 specifying the \fBSA_ONSTACK\fP flag.
 .PP
 The \fIss\fP argument is used to specify a new
 alternate signal stack, while the \fIold_ss\fP argument
 is used to retrieve information about the currently
 established signal stack.
 If we are interested in performing just one
 of these tasks, then the other argument can be specified as NULL.
 .PP
 The
 .I stack_t
 type used to type the arguments of this function is defined as follows:
 .PP
 .in +4n
 .EX
 typedef struct {
     void  *ss_sp;     /* Base address of stack */
     int    ss_flags;  /* Flags */
     size_t ss_size;   /* Number of bytes in stack */
 } stack_t;
 .EE
 .in
 .PP
 To establish a new alternate signal stack,
 the fields of this structure are set as follows:
 .TP
 .I ss.ss_flags
 This field contains either 0, or the following flag:
 .RS
 .TP
 .BR SS_AUTODISARM " (since Linux 4.7)"
 .\" commit 2a74213838104a41588d86fd5e8d344972891ace
 .\" See tools/testing/selftests/sigaltstack/sas.c in kernel sources
 Clear the alternate signal stack settings on entry to the signal handler.
 When the signal handler returns,
 the previous alternate signal stack settings are restored.
 .IP
 This flag was added in order make it safe
 to switch away from the signal handler with
 .BR swapcontext (3).
 Without this flag, a subsequently handled signal will corrupt
 the state of the switched-away signal handler.
 On kernels where this flag is not supported,
 .BR sigaltstack ()
 fails with the error
 .BR EINVAL
 when this flag is supplied.
 .RE
 .TP
 .I ss.ss_sp
 This field specifies the starting address of the stack.
 When a signal handler is invoked on the alternate stack,
 the kernel automatically aligns the address given in \fIss.ss_sp\fP
 to a suitable address boundary for the underlying hardware architecture.
 .TP
 .I ss.ss_size
 This field specifies the size of the stack.
 The constant \fBSIGSTKSZ\fP is defined to be large enough
 to cover the usual size requirements for an alternate signal stack,
 and the constant \fBMINSIGSTKSZ\fP defines the minimum
 size required to execute a signal handler.
 .PP
 To disable an existing stack, specify \fIss.ss_flags\fP
 as \fBSS_DISABLE\fP.
 In this case, the kernel ignores any other flags in
 .IR ss.ss_flags
 and the remaining fields
 in \fIss\fP.
 .PP
 If \fIold_ss\fP is not NULL, then it is used to return information about
 the alternate signal stack which was in effect prior to the
 call to
 .BR sigaltstack ().
 The \fIold_ss.ss_sp\fP and \fIold_ss.ss_size\fP fields return the starting
 address and size of that stack.
 The \fIold_ss.ss_flags\fP may return either of the following values:
 .TP
 .B SS_ONSTACK
 The thread is currently executing on the alternate signal stack.
 (Note that it is not possible
 to change the alternate signal stack if the thread is
 currently executing on it.)
 .TP
 .B SS_DISABLE
 The alternate signal stack is currently disabled.
 .IP
 Alternatively, this value is returned if the thread is currently
 executing on an alternate signal stack that was established using the
 .B SS_AUTODISARM
 flag.
 In this case, it is safe to switch away from the signal handler with
 .BR swapcontext (3).
 It is also possible to set up a different alternative signal stack
 using a further call to
 .BR sigaltstack ().
 .\" FIXME Was it intended that one can set up a different alternative
 .\" signal stack in this scenario? (In passing, if one does this, the
 .\" sigaltstack(NULL, &old_ss) now returns old_ss.ss_flags==SS_AUTODISARM
 .\" rather than old_ss.ss_flags==SS_DISABLE. The API design here seems
 .\" confusing...
 .TP
 .B SS_AUTODISARM
 The alternate signal stack has been marked to be autodisarmed
 as described above.
 .PP
 By specifying
 .I ss
 as NULL, and
 .I old_ss
 as a non-NULL value, one can obtain the current settings for
 the alternate signal stack without changing them.
 .SH RETURN VALUE
 .BR sigaltstack ()
 returns 0 on success, or \-1 on failure with
 \fIerrno\fP set to indicate the error.
 .SH ERRORS
 .TP
 .B EFAULT
 Either \fIss\fP or \fIold_ss\fP is not NULL and points to an area
 outside of the process's address space.
 .TP
 .B EINVAL
 \fIss\fP is not NULL and the \fIss_flags\fP field contains
 an invalid flag.
 .TP
 .B ENOMEM
 The specified size of the new alternate signal stack
 .I ss.ss_size
 was less than
 .BR MINSIGSTKSZ .
 .TP
 .B EPERM
 An attempt was made to change the alternate signal stack while
 it was active (i.e., the thread was already executing
 on the current alternate signal stack).
 .SH ATTRIBUTES
 For an explanation of the terms used in this section, see
 .BR attributes (7).
 .ad l
 .nh
 .TS
 allbox;
 lbx lb lb
 l l l.
 Interface	Attribute	Value
 T{
 .BR sigaltstack ()
 T}	Thread safety	MT-Safe
 .TE
 .hy
 .ad
 .sp 1
 .SH CONFORMING TO
 POSIX.1-2001, POSIX.1-2008, SUSv2, SVr4.
 .PP
 The
 .B SS_AUTODISARM
 flag is a Linux extension.
 .SH NOTES
 The most common usage of an alternate signal stack is to handle the
 .B SIGSEGV
 signal that is generated if the space available for the
 standard stack is exhausted: in this case, a signal handler for
 .B SIGSEGV
 cannot be invoked on the standard stack; if we wish to handle it,
 we must use an alternate signal stack.
 .PP
 Establishing an alternate signal stack is useful if a thread
 expects that it may exhaust its standard stack.
 This may occur, for example, because the stack grows so large
 that it encounters the upwardly growing heap, or it reaches a
 limit established by a call to \fBsetrlimit(RLIMIT_STACK, &rlim)\fP.
 If the standard stack is exhausted, the kernel sends
 the thread a \fBSIGSEGV\fP signal.
 In these circumstances the only way to catch this signal is
 on an alternate signal stack.
 .PP
 On most hardware architectures supported by Linux, stacks grow
 downward.
 .BR sigaltstack ()
 automatically takes account
 of the direction of stack growth.
 .PP
 Functions called from a signal handler executing on an alternate
 signal stack will also use the alternate signal stack.
 (This also applies to any handlers invoked for other signals while
 the thread is executing on the alternate signal stack.)
 Unlike the standard stack, the system does not
 automatically extend the alternate signal stack.
 Exceeding the allocated size of the alternate signal stack will
 lead to unpredictable results.
 .PP
 A successful call to
 .BR execve (2)
 removes any existing alternate
 signal stack.
 A child process created via
 .BR fork (2)
 inherits a copy of its parent's alternate signal stack settings.
 The same is also true for a child process created using
 .BR clone (2),
 unless the clone flags include
 .BR CLONE_VM
 and do not include
 .BR CLONE_VFORK ,
 in which case any alternate signal stack that was established in the parent
 is disabled in the child process.
 .PP
 .BR sigaltstack ()
 supersedes the older
 .BR sigstack ()
 call.
 For backward compatibility, glibc also provides
 .BR sigstack ().
 All new applications should be written using
 .BR sigaltstack ().
 .SS History
 4.2BSD had a
 .BR sigstack ()
 system call.
 It used a slightly
 different struct, and had the major disadvantage that the caller
 had to know the direction of stack growth.
 .SH BUGS
 In Linux 2.2 and earlier, the only flag that could be specified
 in
 .I ss.sa_flags
 was
 .BR SS_DISABLE .
 In the lead up to the release of the Linux 2.4 kernel,
 .\" Linux 2.3.40
 .\" After quite a bit of web and mail archive searching,
 .\" I could not find the patch on any mailing list, and I
 .\" could find no place where the rationale for this change
 .\" explained -- mtk
 a change was made to allow
 .BR sigaltstack ()
 to allow
 .I ss.ss_flags==SS_ONSTACK
 with the same meaning as
 .IR "ss.ss_flags==0"
 (i.e., the inclusion of
 .B SS_ONSTACK
 in
 .I ss.ss_flags
 is a no-op).
 On other implementations, and according to POSIX.1,
 .B SS_ONSTACK
 appears only as a reported flag in
 .IR old_ss.ss_flags .
 On Linux, there is no need ever to specify
 .B SS_ONSTACK
 in
 .IR ss.ss_flags ,
 and indeed doing so should be avoided on portability grounds:
 various other systems
 .\" See the source code of Illumos and FreeBSD, for example.
 give an error if
 .B SS_ONSTACK
 is specified in
 .IR ss.ss_flags .
 .SH EXAMPLES
 The following code segment demonstrates the use of
 .BR sigaltstack ()
 (and
 .BR sigaction (2))
 to install an alternate signal stack that is employed by a handler
 for the
 .BR SIGSEGV
 signal:
 .PP
 .in +4n
 .EX
 stack_t ss;

 ss.ss_sp = malloc(SIGSTKSZ);
 if (ss.ss_sp == NULL) {
     perror("malloc");
     exit(EXIT_FAILURE);
 }

 ss.ss_size = SIGSTKSZ;
 ss.ss_flags = 0;
 if (sigaltstack(&ss, NULL) == \-1) {
     perror("sigaltstack");
     exit(EXIT_FAILURE);
 }

 sa.sa_flags = SA_ONSTACK;
 sa.sa_handler = handler();      /* Address of a signal handler */
 sigemptyset(&sa.sa_mask);
 if (sigaction(SIGSEGV, &sa, NULL) == \-1) {
     perror("sigaction");
     exit(EXIT_FAILURE);
 }
 .EE
 .in
 .SH SEE ALSO
 .BR execve (2),
 .BR setrlimit (2),
 .BR sigaction (2),
 .BR siglongjmp (3),
 .BR sigsetjmp (3),
 .BR signal (7)
	.\" Copyright (c) 2001, 2017 Michael Kerrisk <mtk.manpages@gmail.com>
	.\"
	.\" %%%LICENSE_START(VERBATIM)
	.\" Permission is granted to make and distribute verbatim copies of this
	.\" manual provided the copyright notice and this permission notice are
	.\" preserved on all copies.
	.\"
	.\" Permission is granted to copy and distribute modified versions of this
	.\" manual under the conditions for verbatim copying, provided that the
	.\" entire resulting derived work is distributed under the terms of a
	.\" permission notice identical to this one.
	.\"
	.\" Since the Linux kernel and libraries are constantly changing, this
	.\" manual page may be incorrect or out-of-date. The author(s) assume no
	.\" responsibility for errors or omissions, or for damages resulting from
	.\" the use of the information contained herein. The author(s) may not
	.\" have taken the same level of care in the production of this manual,
	.\" which is licensed free of charge, as they might when working
	.\" professionally.
	.\"
	.\" Formatted or processed versions of this manual, if unaccompanied by
	.\" the source, must acknowledge the copyright and authors of this work.
	.\" %%%LICENSE_END
	.\"
	.\" aeb, various minor fixes
	.TH SIGALTSTACK 2 2021-03-22 "Linux" "Linux Programmer's Manual"
	.SH NAME
	sigaltstack \- set and/or get signal stack context
	.SH SYNOPSIS
	.nf
	.B #include <signal.h>
	.PP
	.BI "int sigaltstack(const stack_t *restrict " ss \
	", stack_t *restrict " old_ss );
	.fi
	.PP
	.RS -4
	Feature Test Macro Requirements for glibc (see
	.BR feature_test_macros (7)):
	.RE
	.PP
	.BR sigaltstack ():
	.nf
	_XOPEN_SOURCE >= 500
	.\" \|\| _XOPEN_SOURCE && _XOPEN_SOURCE_EXTENDED
	\|\| /* Since glibc 2.12: */ _POSIX_C_SOURCE >= 200809L
	\|\| /* Glibc <= 2.19: */ _BSD_SOURCE
	.fi
	.SH DESCRIPTION
	.BR sigaltstack ()
	allows a thread to define a new alternate
	signal stack and/or retrieve the state of an existing
	alternate signal stack.
	An alternate signal stack is used during the
	execution of a signal handler if the establishment of that handler (see
	.BR sigaction (2))
	requested it.
	.PP
	The normal sequence of events for using an alternate signal stack
	is the following:
	.TP 3
	1.
	Allocate an area of memory to be used for the alternate
	signal stack.
	.TP
	2.
	Use
	.BR sigaltstack ()
	to inform the system of the existence and
	location of the alternate signal stack.
	.TP
	3.
	When establishing a signal handler using
	.BR sigaction (2),
	inform the system that the signal handler should be executed
	on the alternate signal stack by
	specifying the \fBSA_ONSTACK\fP flag.
	.PP
	The \fIss\fP argument is used to specify a new
	alternate signal stack, while the \fIold_ss\fP argument
	is used to retrieve information about the currently
	established signal stack.
	If we are interested in performing just one
	of these tasks, then the other argument can be specified as NULL.
	.PP
	The
	.I stack_t
	type used to type the arguments of this function is defined as follows:
	.PP
	.in +4n
	.EX
	typedef struct {
	void ss_sp; / Base address of stack */
	int ss_flags; /* Flags */
	size_t ss_size; /* Number of bytes in stack */
	} stack_t;
	.EE
	.in
	.PP
	To establish a new alternate signal stack,
	the fields of this structure are set as follows:
	.TP
	.I ss.ss_flags
	This field contains either 0, or the following flag:
	.RS
	.TP
	.BR SS_AUTODISARM " (since Linux 4.7)"
	.\" commit 2a74213838104a41588d86fd5e8d344972891ace
	.\" See tools/testing/selftests/sigaltstack/sas.c in kernel sources
	Clear the alternate signal stack settings on entry to the signal handler.
	When the signal handler returns,
	the previous alternate signal stack settings are restored.
	.IP
	This flag was added in order make it safe
	to switch away from the signal handler with
	.BR swapcontext (3).
	Without this flag, a subsequently handled signal will corrupt
	the state of the switched-away signal handler.
	On kernels where this flag is not supported,
	.BR sigaltstack ()
	fails with the error
	.BR EINVAL
	when this flag is supplied.
	.RE
	.TP
	.I ss.ss_sp
	This field specifies the starting address of the stack.
	When a signal handler is invoked on the alternate stack,
	the kernel automatically aligns the address given in \fIss.ss_sp\fP
	to a suitable address boundary for the underlying hardware architecture.
	.TP
	.I ss.ss_size
	This field specifies the size of the stack.
	The constant \fBSIGSTKSZ\fP is defined to be large enough
	to cover the usual size requirements for an alternate signal stack,
	and the constant \fBMINSIGSTKSZ\fP defines the minimum
	size required to execute a signal handler.
	.PP
	To disable an existing stack, specify \fIss.ss_flags\fP
	as \fBSS_DISABLE\fP.
	In this case, the kernel ignores any other flags in
	.IR ss.ss_flags
	and the remaining fields
	in \fIss\fP.
	.PP
	If \fIold_ss\fP is not NULL, then it is used to return information about
	the alternate signal stack which was in effect prior to the
	call to
	.BR sigaltstack ().
	The \fIold_ss.ss_sp\fP and \fIold_ss.ss_size\fP fields return the starting
	address and size of that stack.
	The \fIold_ss.ss_flags\fP may return either of the following values:
	.TP
	.B SS_ONSTACK
	The thread is currently executing on the alternate signal stack.
	(Note that it is not possible
	to change the alternate signal stack if the thread is
	currently executing on it.)
	.TP
	.B SS_DISABLE
	The alternate signal stack is currently disabled.
	.IP
	Alternatively, this value is returned if the thread is currently
	executing on an alternate signal stack that was established using the
	.B SS_AUTODISARM
	flag.
	In this case, it is safe to switch away from the signal handler with
	.BR swapcontext (3).
	It is also possible to set up a different alternative signal stack
	using a further call to
	.BR sigaltstack ().
	.\" FIXME Was it intended that one can set up a different alternative
	.\" signal stack in this scenario? (In passing, if one does this, the
	.\" sigaltstack(NULL, &old_ss) now returns old_ss.ss_flags==SS_AUTODISARM
	.\" rather than old_ss.ss_flags==SS_DISABLE. The API design here seems
	.\" confusing...
	.TP
	.B SS_AUTODISARM
	The alternate signal stack has been marked to be autodisarmed
	as described above.
	.PP
	By specifying
	.I ss
	as NULL, and
	.I old_ss
	as a non-NULL value, one can obtain the current settings for
	the alternate signal stack without changing them.
	.SH RETURN VALUE
	.BR sigaltstack ()
	returns 0 on success, or \-1 on failure with
	\fIerrno\fP set to indicate the error.
	.SH ERRORS
	.TP
	.B EFAULT
	Either \fIss\fP or \fIold_ss\fP is not NULL and points to an area
	outside of the process's address space.
	.TP
	.B EINVAL
	\fIss\fP is not NULL and the \fIss_flags\fP field contains
	an invalid flag.
	.TP
	.B ENOMEM
	The specified size of the new alternate signal stack
	.I ss.ss_size
	was less than
	.BR MINSIGSTKSZ .
	.TP
	.B EPERM
	An attempt was made to change the alternate signal stack while
	it was active (i.e., the thread was already executing
	on the current alternate signal stack).
	.SH ATTRIBUTES
	For an explanation of the terms used in this section, see
	.BR attributes (7).
	.ad l
	.nh
	.TS
	allbox;
	lbx lb lb
	l l l.
	Interface Attribute Value
	T{
	.BR sigaltstack ()
	T} Thread safety MT-Safe
	.TE
	.hy
	.ad
	.sp 1
	.SH CONFORMING TO
	POSIX.1-2001, POSIX.1-2008, SUSv2, SVr4.
	.PP
	The
	.B SS_AUTODISARM
	flag is a Linux extension.
	.SH NOTES
	The most common usage of an alternate signal stack is to handle the
	.B SIGSEGV
	signal that is generated if the space available for the
	standard stack is exhausted: in this case, a signal handler for
	.B SIGSEGV
	cannot be invoked on the standard stack; if we wish to handle it,
	we must use an alternate signal stack.
	.PP
	Establishing an alternate signal stack is useful if a thread
	expects that it may exhaust its standard stack.
	This may occur, for example, because the stack grows so large
	that it encounters the upwardly growing heap, or it reaches a
	limit established by a call to \fBsetrlimit(RLIMIT_STACK, &rlim)\fP.
	If the standard stack is exhausted, the kernel sends
	the thread a \fBSIGSEGV\fP signal.
	In these circumstances the only way to catch this signal is
	on an alternate signal stack.
	.PP
	On most hardware architectures supported by Linux, stacks grow
	downward.
	.BR sigaltstack ()
	automatically takes account
	of the direction of stack growth.
	.PP
	Functions called from a signal handler executing on an alternate
	signal stack will also use the alternate signal stack.
	(This also applies to any handlers invoked for other signals while
	the thread is executing on the alternate signal stack.)
	Unlike the standard stack, the system does not
	automatically extend the alternate signal stack.
	Exceeding the allocated size of the alternate signal stack will
	lead to unpredictable results.
	.PP
	A successful call to
	.BR execve (2)
	removes any existing alternate
	signal stack.
	A child process created via
	.BR fork (2)
	inherits a copy of its parent's alternate signal stack settings.
	The same is also true for a child process created using
	.BR clone (2),
	unless the clone flags include
	.BR CLONE_VM
	and do not include
	.BR CLONE_VFORK ,
	in which case any alternate signal stack that was established in the parent
	is disabled in the child process.
	.PP
	.BR sigaltstack ()
	supersedes the older
	.BR sigstack ()
	call.
	For backward compatibility, glibc also provides
	.BR sigstack ().
	All new applications should be written using
	.BR sigaltstack ().
	.SS History
	4.2BSD had a
	.BR sigstack ()
	system call.
	It used a slightly
	different struct, and had the major disadvantage that the caller
	had to know the direction of stack growth.
	.SH BUGS
	In Linux 2.2 and earlier, the only flag that could be specified
	in
	.I ss.sa_flags
	was
	.BR SS_DISABLE .
	In the lead up to the release of the Linux 2.4 kernel,
	.\" Linux 2.3.40
	.\" After quite a bit of web and mail archive searching,
	.\" I could not find the patch on any mailing list, and I
	.\" could find no place where the rationale for this change
	.\" explained -- mtk
	a change was made to allow
	.BR sigaltstack ()
	to allow
	.I ss.ss_flags==SS_ONSTACK
	with the same meaning as
	.IR "ss.ss_flags==0"
	(i.e., the inclusion of
	.B SS_ONSTACK
	in
	.I ss.ss_flags
	is a no-op).
	On other implementations, and according to POSIX.1,
	.B SS_ONSTACK
	appears only as a reported flag in
	.IR old_ss.ss_flags .
	On Linux, there is no need ever to specify
	.B SS_ONSTACK
	in
	.IR ss.ss_flags ,
	and indeed doing so should be avoided on portability grounds:
	various other systems
	.\" See the source code of Illumos and FreeBSD, for example.
	give an error if
	.B SS_ONSTACK
	is specified in
	.IR ss.ss_flags .
	.SH EXAMPLES
	The following code segment demonstrates the use of
	.BR sigaltstack ()
	(and
	.BR sigaction (2))
	to install an alternate signal stack that is employed by a handler
	for the
	.BR SIGSEGV
	signal:
	.PP
	.in +4n
	.EX
	stack_t ss;

	ss.ss_sp = malloc(SIGSTKSZ);
	if (ss.ss_sp == NULL) {
	perror("malloc");
	exit(EXIT_FAILURE);
	}

	ss.ss_size = SIGSTKSZ;
	ss.ss_flags = 0;
	if (sigaltstack(&ss, NULL) == \-1) {
	perror("sigaltstack");
	exit(EXIT_FAILURE);
	}

	sa.sa_flags = SA_ONSTACK;
	sa.sa_handler = handler(); /* Address of a signal handler */
	sigemptyset(&sa.sa_mask);
	if (sigaction(SIGSEGV, &sa, NULL) == \-1) {
	perror("sigaction");
	exit(EXIT_FAILURE);
	}
	.EE
	.in
	.SH SEE ALSO
	.BR execve (2),
	.BR setrlimit (2),
	.BR sigaction (2),
	.BR siglongjmp (3),
	.BR sigsetjmp (3),
	.BR signal (7)