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263 lines
8.5 KiB
C
263 lines
8.5 KiB
C
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/**
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* \file
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* <!--
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* This file is part of BeRTOS.
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*
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* Bertos is free software; you can redistribute it and/or modify
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* it under the terms of the GNU General Public License as published by
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* the Free Software Foundation; either version 2 of the License, or
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* (at your option) any later version.
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*
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* This program is distributed in the hope that it will be useful,
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* but WITHOUT ANY WARRANTY; without even the implied warranty of
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* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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* GNU General Public License for more details.
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*
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* You should have received a copy of the GNU General Public License
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* along with this program; if not, write to the Free Software
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* Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA
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*
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* As a special exception, you may use this file as part of a free software
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* library without restriction. Specifically, if other files instantiate
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* templates or use macros or inline functions from this file, or you compile
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* this file and link it with other files to produce an executable, this
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* file does not by itself cause the resulting executable to be covered by
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* the GNU General Public License. This exception does not however
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* invalidate any other reasons why the executable file might be covered by
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* the GNU General Public License.
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*
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* Copyright 2004, 2008 Develer S.r.l. (http://www.develer.com/)
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* Copyright 1999, 2000, 2001 Bernie Innocenti <bernie@codewiz.org>
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* -->
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*
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* \brief IPC signals implementation.
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*
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* Signals are a low-level IPC primitive. A process receives a signal
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* when some external event has happened. Like interrupt requests,
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* signals do not carry any additional information. If processing a
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* specific event requires additional data, the process must obtain it
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* through some other mechanism.
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*
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* Despite the name, one shouldn't confuse these signals with POSIX
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* signals. POSIX signals are usually executed synchronously, like
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* software interrupts.
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*
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* Signals are very low overhead. Using them exclusively to wait
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* for multiple asynchronous events results in very simple dispatch
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* logic with low processor and resource usage.
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*
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* The "event" module is a higher-level interface that can optionally
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* deliver signals to processes. Messages provide even higher-level
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* IPC services built on signals. Semaphore arbitration is also
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* implemented using signals.
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*
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* In this implementation, each process has a limited set of signal
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* bits (usually 32) and can wait for multiple signals at the same
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* time using sig_wait(). Signals can also be polled using sig_check(),
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* but a process spinning on its signals usually defeats their purpose
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* of providing a multitasking-friendly infrastructure for event-driven
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* applications.
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*
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* Signals are like flags: they are either active or inactive. After an
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* external event has delivered a particular signal, it remains raised until
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* the process acknowledges it using either sig_wait() or sig_check().
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* Counting signals is not a reliable way to count how many times a
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* particular event has occurred, because the same signal may be
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* delivered twice before the process can notice.
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*
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* Signals can be delivered synchronously via sig_send() or asynchronously via
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* sig_post().
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*
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* In the synchronous case the process is awakened if it was waiting for any
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* signal and immediately dispatched for execution via a direct context switch,
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* if its priority is greater than the running process.
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*
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* <pre>
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* - Synchronous-signal delivery:
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*
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* [P1]____sig_send()____proc_wakeup()____[P2]
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* </pre>
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*
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* In the asynchronous case, the process is scheduled for execution as a
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* consequence of the delivery, but it will be dispatched by the scheduler as
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* usual, according to the scheduling policy.
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*
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* <pre>
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* - Asynchronous-signal delivery:
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*
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* [P1]____sig_post()____[P1]____proc_schedule()____[P2]
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* </pre>
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*
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* In this way, any execution context, including an interrupt handler, can
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* deliver a signal to a process. However, synchronous signal delivery from a
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* non-sleepable context (like an interrupt handler) is forbidden in order to
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* avoid potential deadlock conditions. Instead, sig_post() can be used from
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* any context, expecially from interrupt context or when the preemption is
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* disabled.
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*
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* Multiple independent signals may be delivered at once with a single
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* invocation of sig_send() or sig_post(), although this is rarely useful.
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*
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* \section signal_allocation Signal Allocation
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*
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* There's no hardcoded mapping of specific events to signal bits.
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* The meaning of a particular signal bit is defined by an agreement
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* between the delivering entity and the receiving process.
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* For instance, a terminal driver may be designed to deliver
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* a signal bit called SIG_INT when it reads the CTRL-C sequence
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* from the keyboard, and a process may react to it by quitting.
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*
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* \section sig_single SIG_SINGLE
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*
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* The SIG_SINGLE bit is reserved as a convenient shortcut in those
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* simple scenarios where a process needs to wait on just one event
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* synchronously. By using SIG_SINGLE, there's no need to allocate
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* a specific signal from the free pool. The constraints for safely
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* accessing SIG_SINGLE are:
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* - The process MUST sig_wait() exclusively on SIG_SINGLE
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* - SIG_SIGNAL MUST NOT be left pending after use (sig_wait() will reset
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* it automatically)
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* - Do not sleep between starting the asynchronous task that will fire
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* SIG_SINGLE, and the call to sig_wait().
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* - Do not call system functions that may implicitly sleep, such as
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* timer_delayTicks().
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*
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* \author Bernie Innocenti <bernie@codewiz.org>
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*/
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#include "signal.h"
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#include "cfg/cfg_timer.h"
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#include <cfg/debug.h>
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#include <cfg/depend.h>
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#include <cpu/irq.h>
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#include <kern/proc.h>
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#include <kern/proc_p.h>
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#if CONFIG_KERN_SIGNALS
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// Check config dependencies
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CONFIG_DEPEND(CONFIG_KERN_SIGNALS, CONFIG_KERN);
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sigmask_t sig_waitSignal(Signal *s, sigmask_t sigs)
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{
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sigmask_t result;
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/* Sleeping with IRQs disabled or preemption forbidden is illegal */
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IRQ_ASSERT_ENABLED();
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ASSERT(proc_preemptAllowed());
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/*
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* This is subtle: there's a race condition where a concurrent process
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* or an interrupt may call sig_send()/sig_post() to set a bit in
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* Process.sig_recv just after we have checked for it, but before we've
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* set Process.sig_wait to let them know we want to be awaken.
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*
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* In this case, we'd deadlock with the signal bit already set and the
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* process never being reinserted into the ready list.
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*/
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IRQ_DISABLE;
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/* Loop until we get at least one of the signals */
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while (!(result = s->recv & sigs))
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{
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/*
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* Tell "them" that we want to be awaken when any of these
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* signals arrives.
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*/
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s->wait = sigs;
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/* Go to sleep and proc_switch() to another process. */
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proc_switch();
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/*
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* When we come back here, the wait mask must have been
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* cleared by someone through sig_send()/sig_post(), and at
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* least one of the signals we were expecting must have been
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* delivered to us.
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*/
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ASSERT(!s->wait);
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ASSERT(s->recv & sigs);
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}
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/* Signals found: clear them and return */
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s->recv &= ~sigs;
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IRQ_ENABLE;
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return result;
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}
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#if CONFIG_TIMER_EVENTS
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#include <drv/timer.h>
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sigmask_t sig_waitTimeoutSignal(Signal *s, sigmask_t sigs, ticks_t timeout,
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Hook func, iptr_t data)
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{
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Timer t;
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sigmask_t res;
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cpu_flags_t flags;
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ASSERT(!sig_checkSignal(s, SIG_TIMEOUT));
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ASSERT(!(sigs & SIG_TIMEOUT));
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/* IRQ are needed to run timer */
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ASSERT(IRQ_ENABLED());
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if (func)
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timer_setSoftint(&t, func, data);
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else
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timer_set_event_signal(&t, proc_current(), SIG_TIMEOUT);
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timer_setDelay(&t, timeout);
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timer_add(&t);
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res = sig_waitSignal(s, SIG_TIMEOUT | sigs);
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IRQ_SAVE_DISABLE(flags);
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/* Remove timer if sigs occur before timer signal */
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if (!(res & SIG_TIMEOUT) && !sig_checkSignal(s, SIG_TIMEOUT))
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timer_abort(&t);
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IRQ_RESTORE(flags);
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return res;
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}
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#endif // CONFIG_TIMER_EVENTS
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INLINE void __sig_signal(Signal *s, Process *proc, sigmask_t sigs, bool wakeup)
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{
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cpu_flags_t flags;
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IRQ_SAVE_DISABLE(flags);
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/* Set the signals */
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s->recv |= sigs;
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/* Check if process needs to be awoken */
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if (s->recv & s->wait)
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{
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ASSERT(proc != current_process);
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s->wait = 0;
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if (wakeup)
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proc_wakeup(proc);
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else
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SCHED_ENQUEUE_HEAD(proc);
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}
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IRQ_RESTORE(flags);
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}
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void sig_sendSignal(Signal *s, Process *proc, sigmask_t sigs)
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{
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ASSERT_USER_CONTEXT();
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IRQ_ASSERT_ENABLED();
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ASSERT(proc_preemptAllowed());
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__sig_signal(s, proc, sigs, true);
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}
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void sig_postSignal(Signal *s, Process *proc, sigmask_t sigs)
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{
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__sig_signal(s, proc, sigs, false);
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}
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#endif /* CONFIG_KERN_SIGNALS */
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