255 lines
10 KiB
Perl
255 lines
10 KiB
Perl
.\" Copyright (c) 1983 The Regents of the University of California.
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.\" All rights reserved.
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.\"
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.\" Redistribution and use in source and binary forms, with or without
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.\" modification, are permitted provided that the following conditions
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.\" are met:
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.\" 1. Redistributions of source code must retain the above copyright
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.\" notice, this list of conditions and the following disclaimer.
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.\" 2. Redistributions in binary form must reproduce the above copyright
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.\" notice, this list of conditions and the following disclaimer in the
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.\" documentation and/or other materials provided with the distribution.
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.\" 3. All advertising materials mentioning features or use of this software
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.\" must display the following acknowledgement:
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.\" This product includes software developed by the University of
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.\" California, Berkeley and its contributors.
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.\" 4. Neither the name of the University nor the names of its contributors
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.\" may be used to endorse or promote products derived from this software
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.\" without specific prior written permission.
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.\"
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.\" THIS SOFTWARE IS PROVIDED BY THE REGENTS AND CONTRIBUTORS ``AS IS'' AND
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.\" ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
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.\" IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
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.\" ARE DISCLAIMED. IN NO EVENT SHALL THE REGENTS OR CONTRIBUTORS BE LIABLE
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.\" FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
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.\" DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
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.\" OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
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.\" HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
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.\" LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
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.\" OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
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.\" SUCH DAMAGE.
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.\"
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.\" @(#)1.3.t 6.3 (Berkeley) 4/17/91
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.\"
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.sh "Signals
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.PP
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.NH 3
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Overview
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.PP
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The system defines a set of \fIsignals\fP that may be delivered
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to a process. Signal delivery resembles the occurrence of a hardware
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interrupt: the signal is blocked from further occurrence,
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the current process context is saved, and a new one
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is built. A process may specify
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the \fIhandler\fP to which a signal is delivered, or specify that
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the signal is to be \fIblocked\fP or \fIignored\fP. A process may
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also specify that a
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\fIdefault\fP action is to be taken when signals occur.
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.PP
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Some signals
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will cause a process to exit when they are not caught. This
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may be accompanied by creation of a \fIcore\fP image file, containing
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the current memory image of the process for use in post-mortem debugging.
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A process may choose to have signals delivered on a special
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stack, so that sophisticated software stack manipulations are possible.
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.PP
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All signals have the same \fIpriority\fP. If multiple signals
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are pending simultaneously, the order in which they are delivered
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to a process is implementation specific. Signal routines execute
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with the signal that caused their invocation \fIblocked\fP, but other
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signals may yet occur. Mechanisms are provided whereby critical sections
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of code may protect themselves against the occurrence of specified signals.
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.NH 3
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Signal types
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.PP
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The signals defined by the system fall into one of
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five classes: hardware conditions,
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software conditions, input/output notification, process control, or
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resource control.
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The set of signals is defined in the file \fI<signal.h>\fP.
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.PP
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Hardware signals are derived from exceptional conditions which
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may occur during
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execution. Such signals include SIGFPE representing floating
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point and other arithmetic exceptions, SIGILL for illegal instruction
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execution, SIGSEGV for addresses outside the currently assigned
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area of memory, and SIGBUS for accesses that violate memory
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protection constraints.
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Other, more cpu-specific hardware signals exist,
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such as those for the various customer-reserved instructions on
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the VAX (SIGIOT, SIGEMT, and SIGTRAP).
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.PP
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Software signals reflect interrupts generated by user request:
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SIGINT for the normal interrupt signal; SIGQUIT for the more
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powerful \fIquit\fP signal, that normally causes a core image
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to be generated; SIGHUP and SIGTERM that cause graceful
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process termination, either because a user has ``hung up'', or
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by user or program request; and SIGKILL, a more powerful termination
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signal which a process cannot catch or ignore.
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Programs may define their own asynchronous events using SIGUSR1
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and SIGUSR2.
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Other software signals (SIGALRM, SIGVTALRM, SIGPROF)
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indicate the expiration of interval timers.
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.PP
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A process can request notification via a SIGIO signal
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when input or output is possible
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on a descriptor, or when a \fInon-blocking\fP operation completes.
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A process may request to receive a SIGURG signal when an
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urgent condition arises.
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.PP
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A process may be \fIstopped\fP by a signal sent to it or the members
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of its process group. The SIGSTOP signal is a powerful stop
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signal, because it cannot be caught. Other stop signals
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SIGTSTP, SIGTTIN, and SIGTTOU are used when a user request, input
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request, or output request respectively is the reason for stopping the process.
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A SIGCONT signal is sent to a process when it is
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continued from a stopped state.
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Processes may receive notification with a SIGCHLD signal when
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a child process changes state, either by stopping or by terminating.
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.PP
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Exceeding resource limits may cause signals to be generated.
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SIGXCPU occurs when a process nears its CPU time limit and SIGXFSZ
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warns that the limit on file size creation has been reached.
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.NH 3
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Signal handlers
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.PP
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A process has a handler associated with each signal.
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The handler controls the way the signal is delivered.
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The call
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.DS
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#include <signal.h>
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._f
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struct sigvec {
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int (*sv_handler)();
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int sv_mask;
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int sv_flags;
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};
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sigvec(signo, sv, osv)
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int signo; struct sigvec *sv; result struct sigvec *osv;
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.DE
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assigns interrupt handler address \fIsv_handler\fP to signal \fIsigno\fP.
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Each handler address
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specifies either an interrupt routine for the signal, that the
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signal is to be ignored,
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or that a default action (usually process termination) is to occur
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if the signal occurs.
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The constants
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SIG_IGN and SIG_DEF used as values for \fIsv_handler\fP
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cause ignoring or defaulting of a condition.
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The \fIsv_mask\fP value specifies the
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signal mask to be used when the handler is invoked; it implicitly includes
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the signal which invoked the handler.
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Signal masks include one bit for each signal;
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the mask for a signal \fIsigno\fP is provided by the macro
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\fIsigmask\fP(\fIsigno\fP), from \fI<signal.h>\fP.
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\fISv_flags\fP specifies whether system calls should be
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restarted if the signal handler returns and
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whether the handler should operate on the normal run-time
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stack or a special signal stack (see below). If \fIosv\fP
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is non-zero, the previous signal vector is returned.
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.PP
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When a signal condition arises for a process, the signal
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is added to a set of signals pending for the process.
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If the signal is not currently \fIblocked\fP by the process
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then it will be delivered. The process of signal delivery
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adds the signal to be delivered and those signals
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specified in the associated signal
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handler's \fIsv_mask\fP to a set of those \fImasked\fP
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for the process, saves the current process context,
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and places the process in the context of the signal
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handling routine. The call is arranged so that if the signal
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handling routine exits normally the signal mask will be restored
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and the process will resume execution in the original context.
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If the process wishes to resume in a different context, then
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it must arrange to restore the signal mask itself.
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.PP
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The mask of \fIblocked\fP signals is independent of handlers for
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signals. It delays signals from being delivered much as a
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raised hardware interrupt priority level delays hardware interrupts.
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Preventing an interrupt from occurring by changing the handler is analogous to
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disabling a device from further interrupts.
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.PP
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The signal handling routine \fIsv_handler\fP is called by a C call
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of the form
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.DS
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(*sv_handler)(signo, code, scp);
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int signo; long code; struct sigcontext *scp;
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.DE
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The \fIsigno\fP gives the number of the signal that occurred, and
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the \fIcode\fP, a word of information supplied by the hardware.
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The \fIscp\fP parameter is a pointer to a machine-dependent
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structure containing the information for restoring the
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context before the signal.
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.NH 3
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Sending signals
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.PP
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A process can send a signal to another process or group of processes
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with the calls:
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.DS
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kill(pid, signo)
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int pid, signo;
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killpgrp(pgrp, signo)
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int pgrp, signo;
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.DE
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Unless the process sending the signal is privileged,
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it must have the same effective user id as the process receiving the signal.
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.PP
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Signals are also sent implicitly from a terminal device to the
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process group associated with the terminal when certain input characters
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are typed.
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.NH 3
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Protecting critical sections
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.PP
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To block a section of code against one or more signals, a \fIsigblock\fP
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call may be used to add a set of signals to the existing mask, returning
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the old mask:
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.DS
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oldmask = sigblock(mask);
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result long oldmask; long mask;
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.DE
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The old mask can then be restored later with \fIsigsetmask\fP\|,
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.DS
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oldmask = sigsetmask(mask);
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result long oldmask; long mask;
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.DE
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The \fIsigblock\fP call can be used to read the current mask
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by specifying an empty \fImask\fP\|.
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.PP
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It is possible to check conditions with some signals blocked,
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and then to pause waiting for a signal and restoring the mask, by using:
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.DS
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sigpause(mask);
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long mask;
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.DE
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.NH 3
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Signal stacks
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.PP
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Applications that maintain complex or fixed size stacks can use
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the call
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.DS
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._f
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struct sigstack {
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caddr_t ss_sp;
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int ss_onstack;
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};
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sigstack(ss, oss)
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struct sigstack *ss; result struct sigstack *oss;
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.DE
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to provide the system with a stack based at \fIss_sp\fP for delivery
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of signals. The value \fIss_onstack\fP indicates whether the
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process is currently on the signal stack,
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a notion maintained in software by the system.
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.PP
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When a signal is to be delivered, the system checks whether
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the process is on a signal stack. If not, then the process is switched
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to the signal stack for delivery, with the return from the signal
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arranged to restore the previous stack.
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.PP
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If the process wishes to take a non-local exit from the signal routine,
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or run code from the signal stack that uses a different stack,
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a \fIsigstack\fP call should be used to reset the signal stack.
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