392 lines
11 KiB
C
392 lines
11 KiB
C
/* Copyright (C) 2002-2021 Free Software Foundation, Inc.
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This file is part of GCC.
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GCC is free software; you can redistribute it and/or modify it under
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the terms of the GNU General Public License as published by the Free
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Software Foundation; either version 3, or (at your option) any later
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version.
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GCC is distributed in the hope that it will be useful, but WITHOUT ANY
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WARRANTY; without even the implied warranty of MERCHANTABILITY or
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FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
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for more details.
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Under Section 7 of GPL version 3, you are granted additional
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permissions described in the GCC Runtime Library Exception, version
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3.1, as published by the Free Software Foundation.
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You should have received a copy of the GNU General Public License and
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a copy of the GCC Runtime Library Exception along with this program;
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see the files COPYING3 and COPYING.RUNTIME respectively. If not, see
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<http://www.gnu.org/licenses/>. */
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/* Threads compatibility routines for libgcc2 for VxWorks.
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This file implements the GTHREAD_CXX0X part of the interface
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exposed by gthr-vxworks.h, using APIs exposed by regular (!AE/653)
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VxWorks kernels. */
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#include "gthr.h"
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#if __GTHREADS_CXX0X
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#include <taskLib.h>
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#include <stdlib.h>
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#define __TIMESPEC_TO_NSEC(timespec) \
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((long long)timespec.tv_sec * 1000000000 + (long long)timespec.tv_nsec)
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#define __TIMESPEC_TO_TICKS(timespec) \
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((long long)(sysClkRateGet() * __TIMESPEC_TO_NSEC(timespec) + 999999999) \
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/ 1000000000)
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#ifdef __RTP__
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void tls_delete_hook (void);
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#define __CALL_DELETE_HOOK(tcb) tls_delete_hook()
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#else
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/* In kernel mode, we need to pass the TCB to task_delete_hook. The TCB is
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the pointer to the WIND_TCB structure and is the ID of the task. */
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void tls_delete_hook (void *TCB);
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#define __CALL_DELETE_HOOK(tcb) tls_delete_hook((WIND_TCB *) ((tcb)->task_id))
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#endif
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int
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__gthread_cond_signal (__gthread_cond_t *cond)
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{
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if (!cond)
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return ERROR;
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/* If nobody is waiting, skip the semGive altogether: no one can get
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in line while we hold the mutex associated with *COND. We could
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skip this test altogether, but it's presumed cheaper than going
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through the give and take below, and that a signal without a
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waiter occurs often enough for the test to be worth it. */
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SEM_INFO info;
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memset (&info, 0, sizeof (info));
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__RETURN_ERRNO_IF_NOT_OK (semInfoGet (*cond, &info));
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if (info.numTasks == 0)
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return OK;
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int ret = __CHECK_RESULT (semGive (*cond));
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/* It might be the case, however, that when we called semInfo, there
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was a waiter just about to timeout, and by the time we called
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semGive, it had already timed out, so our semGive would leave the
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*cond semaphore full, so the next caller of wait would pass
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through. We don't want that. So, make sure we leave the
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semaphore empty. Despite the window in which the semaphore will
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be full, this works because:
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- we're holding the mutex, so nobody else can semGive, and any
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pending semTakes are actually within semExchange. there might
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be others blocked to acquire the mutex, but those are not
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relevant for the analysis.
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- if there was another non-timed out waiter, semGive will wake it
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up immediately instead of leaving the semaphore full, so the
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semTake below will time out, and the semantics are as expected
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- otherwise, if all waiters timed out before the semGive (or if
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there weren't any to begin with), our semGive completed leaving
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the semaphore full, and our semTake below will consume it
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before any other waiter has a change to reach the semExchange,
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because we're holding the mutex. */
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if (ret == OK)
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semTake (*cond, NO_WAIT);
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return ret;
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}
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/* -------------------- Timed Condition Variables --------------------- */
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int
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__gthread_cond_timedwait (__gthread_cond_t *cond,
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__gthread_mutex_t *mutex,
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const __gthread_time_t *abs_timeout)
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{
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if (!cond)
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return ERROR;
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if (!mutex)
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return ERROR;
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if (!abs_timeout)
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return ERROR;
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struct timespec current;
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if (clock_gettime (CLOCK_REALTIME, ¤t) == ERROR)
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/* CLOCK_REALTIME is not supported. */
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return ERROR;
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const long long abs_timeout_ticks = __TIMESPEC_TO_TICKS ((*abs_timeout));
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const long long current_ticks = __TIMESPEC_TO_TICKS (current);
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long long waiting_ticks;
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if (current_ticks < abs_timeout_ticks)
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waiting_ticks = abs_timeout_ticks - current_ticks;
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else
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/* The point until we would need to wait is in the past,
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no need to wait at all. */
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waiting_ticks = 0;
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/* We check that waiting_ticks can be safely casted as an int. */
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if (waiting_ticks > INT_MAX)
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waiting_ticks = INT_MAX;
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int ret = __CHECK_RESULT (semExchange (*mutex, *cond, waiting_ticks));
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__RETURN_ERRNO_IF_NOT_OK (semTake (*mutex, WAIT_FOREVER));
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return ret;
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}
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/* --------------------------- Timed Mutexes ------------------------------ */
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int
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__gthread_mutex_timedlock (__gthread_mutex_t *m,
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const __gthread_time_t *abs_time)
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{
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if (!m)
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return ERROR;
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if (!abs_time)
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return ERROR;
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struct timespec current;
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if (clock_gettime (CLOCK_REALTIME, ¤t) == ERROR)
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/* CLOCK_REALTIME is not supported. */
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return ERROR;
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const long long abs_timeout_ticks = __TIMESPEC_TO_TICKS ((*abs_time));
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const long long current_ticks = __TIMESPEC_TO_TICKS (current);
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long long waiting_ticks;
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if (current_ticks < abs_timeout_ticks)
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waiting_ticks = abs_timeout_ticks - current_ticks;
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else
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/* The point until we would need to wait is in the past,
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no need to wait at all. */
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waiting_ticks = 0;
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/* Make sure that waiting_ticks can be safely casted as an int. */
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if (waiting_ticks > INT_MAX)
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waiting_ticks = INT_MAX;
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return __CHECK_RESULT (semTake (*m, waiting_ticks));
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}
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int
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__gthread_recursive_mutex_timedlock (__gthread_recursive_mutex_t *mutex,
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const __gthread_time_t *abs_timeout)
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{
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return __gthread_mutex_timedlock ((__gthread_mutex_t *)mutex, abs_timeout);
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}
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/* ------------------------------ Threads --------------------------------- */
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/* Task control block initialization and destruction functions. */
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int
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__init_gthread_tcb (__gthread_t __tcb)
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{
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if (!__tcb)
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return ERROR;
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__gthread_mutex_init (&(__tcb->return_value_available));
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if (__tcb->return_value_available == SEM_ID_NULL)
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return ERROR;
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__gthread_mutex_init (&(__tcb->delete_ok));
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if (__tcb->delete_ok == SEM_ID_NULL)
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goto return_sem_delete;
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/* We lock the two mutexes used for signaling. */
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if (__gthread_mutex_lock (&(__tcb->delete_ok)) != OK)
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goto delete_sem_delete;
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if (__gthread_mutex_lock (&(__tcb->return_value_available)) != OK)
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goto delete_sem_delete;
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__tcb->task_id = TASK_ID_NULL;
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return OK;
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delete_sem_delete:
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semDelete (__tcb->delete_ok);
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return_sem_delete:
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semDelete (__tcb->return_value_available);
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return ERROR;
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}
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/* Here, we pass a pointer to a tcb to allow calls from
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cleanup attributes. */
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void
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__delete_gthread_tcb (__gthread_t* __tcb)
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{
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semDelete ((*__tcb)->return_value_available);
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semDelete ((*__tcb)->delete_ok);
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free (*__tcb);
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}
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/* This __gthread_t stores the address of the TCB malloc'ed in
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__gthread_create. It is then accessible via __gthread_self(). */
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__thread __gthread_t __local_tcb = NULL;
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__gthread_t
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__gthread_self (void)
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{
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if (!__local_tcb)
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{
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/* We are in the initial thread, we need to initialize the TCB. */
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__local_tcb = malloc (sizeof (*__local_tcb));
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if (!__local_tcb)
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return NULL;
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if (__init_gthread_tcb (__local_tcb) != OK)
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{
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__delete_gthread_tcb (&__local_tcb);
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return NULL;
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}
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/* We do not set the mutexes in the structure as a thread is not supposed
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to join or detach himself. */
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__local_tcb->task_id = taskIdSelf ();
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}
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return __local_tcb;
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}
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int
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__task_wrapper (__gthread_t tcb, FUNCPTR __func, _Vx_usr_arg_t __args)
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{
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if (!tcb)
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return ERROR;
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__local_tcb = tcb;
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/* We use this variable to avoid memory leaks in the case where
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the underlying function throws an exception. */
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__attribute__ ((cleanup (__delete_gthread_tcb))) __gthread_t __tmp = tcb;
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void *return_value = (void *) __func (__args);
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tcb->return_value = return_value;
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/* Call the destructors. */
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__CALL_DELETE_HOOK (tcb);
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/* Future calls of join() will be able to retrieve the return value. */
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__gthread_mutex_unlock (&tcb->return_value_available);
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/* We wait for the thread to be joined or detached. */
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__gthread_mutex_lock (&(tcb->delete_ok));
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__gthread_mutex_unlock (&(tcb->delete_ok));
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/* Memory deallocation is done by the cleanup attribute of the tmp variable. */
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return OK;
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}
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/* Proper gthreads API. */
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int
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__gthread_create (__gthread_t * __threadid, void *(*__func) (void *),
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void *__args)
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{
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if (!__threadid)
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return ERROR;
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int priority;
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__RETURN_ERRNO_IF_NOT_OK (taskPriorityGet (taskIdSelf (), &priority));
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int options;
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__RETURN_ERRNO_IF_NOT_OK (taskOptionsGet (taskIdSelf (), &options));
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#if defined (__SPE__)
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options |= VX_SPE_TASK;
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#else
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options |= VX_FP_TASK;
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#endif
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options &= VX_USR_TASK_OPTIONS;
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int stacksize = 20 * 1024;
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__gthread_t tcb = malloc (sizeof (*tcb));
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if (!tcb)
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return ERROR;
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if (__init_gthread_tcb (tcb) != OK)
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{
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free (tcb);
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return ERROR;
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}
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TASK_ID task_id = taskCreate (NULL,
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priority, options, stacksize,
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(FUNCPTR) & __task_wrapper,
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(_Vx_usr_arg_t) tcb,
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(_Vx_usr_arg_t) __func,
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(_Vx_usr_arg_t) __args,
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0, 0, 0, 0, 0, 0, 0);
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/* If taskCreate succeeds, task_id will be a valid TASK_ID and not zero. */
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__RETURN_ERRNO_IF_NOT_OK (!task_id);
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tcb->task_id = task_id;
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*__threadid = tcb;
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return __CHECK_RESULT (taskActivate (task_id));
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}
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int
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__gthread_equal (__gthread_t __t1, __gthread_t __t2)
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{
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return (__t1 == __t2) ? OK : ERROR;
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}
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int
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__gthread_yield (void)
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{
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return taskDelay (0);
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}
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int
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__gthread_join (__gthread_t __threadid, void **__value_ptr)
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{
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if (!__threadid)
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return ERROR;
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/* A thread cannot join itself. */
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if (__threadid->task_id == taskIdSelf ())
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return ERROR;
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/* Waiting for the task to set the return value. */
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__gthread_mutex_lock (&__threadid->return_value_available);
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__gthread_mutex_unlock (&__threadid->return_value_available);
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if (__value_ptr)
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*__value_ptr = __threadid->return_value;
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/* The task will be safely be deleted. */
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__gthread_mutex_unlock (&(__threadid->delete_ok));
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__RETURN_ERRNO_IF_NOT_OK (taskWait (__threadid->task_id, WAIT_FOREVER));
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return OK;
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}
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int
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__gthread_detach (__gthread_t __threadid)
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{
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if (!__threadid)
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return ERROR;
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if (taskIdVerify (__threadid->task_id) != OK)
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return ERROR;
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/* The task will be safely be deleted. */
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__gthread_mutex_unlock (&(__threadid->delete_ok));
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return OK;
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}
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#endif
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