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guile/libguile/threads.c
Marius Vollmer 6087fad9c7 (gc_section_count): Removed, thread-sleeping can not 
be nested.
(scm_i_thread_put_to_sleep): Call scm_i_leave_guile before locking
admin mutex so that we can be put to sleep by other threads while
blocking on that mutex.  Lock all the heap mutex of all threads,
including ourselves.
(scm_i_thread_wake_up): Unlock all threads, including ourselves,
call scm_i_enter_guile.
(scm_thread_mark_stacks): Expect all threads to be suspended.
2004-08-19 17:16:01 +00:00

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/* Copyright (C) 1995,1996,1997,1998,2000,2001, 2002, 2003, 2004 Free Software Foundation, Inc.
*
* This library is free software; you can redistribute it and/or
* modify it under the terms of the GNU Lesser General Public
* License as published by the Free Software Foundation; either
* version 2.1 of the License, or (at your option) any later version.
*
* This library is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
* Lesser General Public License for more details.
*
* You should have received a copy of the GNU Lesser General Public
* License along with this library; if not, write to the Free Software
* Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
*/
/* This file implements nice Scheme level threads on top of the gastly
C level threads.
*/
#include "libguile/_scm.h"
#if HAVE_UNISTD_H
#include <unistd.h>
#endif
#include <stdio.h>
#include <assert.h>
#if HAVE_SYS_TIME_H
#include <sys/time.h>
#endif
#include "libguile/validate.h"
#include "libguile/root.h"
#include "libguile/eval.h"
#include "libguile/async.h"
#include "libguile/ports.h"
#include "libguile/threads.h"
#include "libguile/dynwind.h"
#include "libguile/iselect.h"
/*** Queues */
static SCM
make_queue ()
{
return scm_cons (SCM_EOL, SCM_EOL);
}
static SCM
enqueue (SCM q, SCM t)
{
SCM c = scm_cons (t, SCM_EOL);
if (SCM_NULLP (SCM_CDR (q)))
SCM_SETCDR (q, c);
else
SCM_SETCDR (SCM_CAR (q), c);
SCM_SETCAR (q, c);
return c;
}
static void
remqueue (SCM q, SCM c)
{
SCM p, prev = q;
for (p = SCM_CDR (q); !SCM_NULLP (p); p = SCM_CDR (p))
{
if (scm_is_eq (p, c))
{
if (scm_is_eq (c, SCM_CAR (q)))
SCM_SETCAR (q, SCM_CDR (c));
SCM_SETCDR (prev, SCM_CDR (c));
return;
}
prev = p;
}
abort ();
}
static SCM
dequeue (SCM q)
{
SCM c = SCM_CDR (q);
if (SCM_NULLP (c))
return SCM_BOOL_F;
else
{
SCM_SETCDR (q, SCM_CDR (c));
if (SCM_NULLP (SCM_CDR (q)))
SCM_SETCAR (q, SCM_EOL);
return SCM_CAR (c);
}
}
/*** Threads */
#define THREAD_INITIALIZED_P(t) (t->base != NULL)
struct scm_thread {
/* Blocking.
*/
scm_t_cond sleep_cond;
struct scm_thread *next_waiting;
/* This mutex represents this threads right to access the heap.
That right can temporarily be taken away by the GC. */
scm_t_mutex heap_mutex;
int clear_freelists_p; /* set if GC was done while thread was asleep */
scm_root_state *root;
SCM handle;
scm_t_thread thread;
SCM result;
int exited;
/* For keeping track of the stack and registers. */
SCM_STACKITEM *base;
SCM_STACKITEM *top;
jmp_buf regs;
};
static SCM
make_thread (SCM creation_protects)
{
SCM z;
scm_thread *t;
z = scm_make_smob (scm_tc16_thread);
t = SCM_THREAD_DATA (z);
t->handle = z;
t->result = creation_protects;
t->base = NULL;
scm_i_plugin_cond_init (&t->sleep_cond, 0);
scm_i_plugin_mutex_init (&t->heap_mutex, &scm_i_plugin_mutex);
t->clear_freelists_p = 0;
t->exited = 0;
return z;
}
static void
init_thread_creatant (SCM thread,
SCM_STACKITEM *base)
{
scm_thread *t = SCM_THREAD_DATA (thread);
t->thread = scm_thread_self ();
t->base = base;
t->top = NULL;
}
static SCM
thread_mark (SCM obj)
{
scm_thread *t = SCM_THREAD_DATA (obj);
scm_gc_mark (t->result);
return t->root->handle; /* mark root-state of this thread */
}
static int
thread_print (SCM exp, SCM port, scm_print_state *pstate SCM_UNUSED)
{
scm_thread *t = SCM_THREAD_DATA (exp);
scm_puts ("#<thread ", port);
scm_intprint ((unsigned long)t->thread, 10, port);
scm_puts (" (", port);
scm_intprint ((unsigned long)t, 16, port);
scm_puts (")>", port);
return 1;
}
static size_t
thread_free (SCM obj)
{
scm_thread *t = SCM_THREAD_DATA (obj);
if (!t->exited)
abort ();
scm_gc_free (t, sizeof (*t), "thread");
return 0;
}
/*** Scheduling */
#define cur_thread (SCM_CURRENT_THREAD->handle)
scm_t_key scm_i_thread_key;
scm_t_key scm_i_root_state_key;
void
scm_i_set_thread_data (void *data)
{
scm_thread *t = SCM_CURRENT_THREAD;
scm_setspecific (scm_i_root_state_key, data);
t->root = (scm_root_state *)data;
}
static void
resume (scm_thread *t)
{
t->top = NULL;
if (t->clear_freelists_p)
{
*SCM_FREELIST_LOC (scm_i_freelist) = SCM_EOL;
*SCM_FREELIST_LOC (scm_i_freelist2) = SCM_EOL;
t->clear_freelists_p = 0;
}
}
void
scm_i_enter_guile (scm_thread *t)
{
scm_i_plugin_mutex_lock (&t->heap_mutex);
resume (t);
}
static scm_thread *
suspend ()
{
scm_thread *c = SCM_CURRENT_THREAD;
/* record top of stack for the GC */
c->top = SCM_STACK_PTR (&c);
/* save registers. */
SCM_FLUSH_REGISTER_WINDOWS;
setjmp (c->regs);
return c;
}
scm_thread *
scm_i_leave_guile ()
{
scm_thread *t = suspend ();
scm_i_plugin_mutex_unlock (&t->heap_mutex);
return t;
}
/* Put the current thread to sleep until it is explicitely unblocked.
*/
static int
block ()
{
int err;
scm_thread *t = suspend ();
err = scm_i_plugin_cond_wait (&t->sleep_cond, &t->heap_mutex);
resume (t);
return err;
}
/* Put the current thread to sleep until it is explicitely unblocked
or until a signal arrives or until time AT (absolute time) is
reached. Return 0 when it has been unblocked; errno otherwise.
*/
static int
timed_block (const scm_t_timespec *at)
{
int err;
scm_thread *t = suspend ();
err = scm_i_plugin_cond_timedwait (&t->sleep_cond, &t->heap_mutex, at);
resume (t);
return err;
}
/* Unblock a sleeping thread.
*/
static void
unblock (scm_thread *t)
{
scm_i_plugin_cond_signal (&t->sleep_cond);
}
/*** Thread creation */
static scm_t_mutex thread_admin_mutex;
static SCM all_threads;
static int thread_count;
typedef struct launch_data {
SCM thread;
SCM rootcont;
scm_t_catch_body body;
void *body_data;
scm_t_catch_handler handler;
void *handler_data;
} launch_data;
static SCM
body_bootstrip (launch_data* data)
{
/* First save the new root continuation */
data->rootcont = scm_root->rootcont;
return (data->body) (data->body_data);
}
static SCM
handler_bootstrip (launch_data* data, SCM tag, SCM throw_args)
{
scm_root->rootcont = data->rootcont;
return (data->handler) (data->handler_data, tag, throw_args);
}
static void
really_launch (SCM_STACKITEM *base, launch_data *data)
{
SCM thread;
scm_thread *t;
thread = data->thread;
t = SCM_THREAD_DATA (thread);
SCM_FREELIST_CREATE (scm_i_freelist);
SCM_FREELIST_CREATE (scm_i_freelist2);
scm_setspecific (scm_i_thread_key, t);
scm_setspecific (scm_i_root_state_key, t->root);
scm_i_plugin_mutex_lock (&t->heap_mutex); /* ensure that we "own" the heap */
init_thread_creatant (thread, base); /* must own the heap */
data->rootcont = SCM_BOOL_F;
t->result =
scm_internal_cwdr ((scm_t_catch_body) body_bootstrip,
data,
(scm_t_catch_handler) handler_bootstrip,
data, base);
scm_i_leave_guile (); /* release the heap */
free (data);
scm_i_plugin_mutex_lock (&thread_admin_mutex);
all_threads = scm_delq_x (thread, all_threads);
t->exited = 1;
thread_count--;
/* detach before unlocking in order to not become joined when detached */
scm_thread_detach (t->thread);
scm_i_plugin_mutex_unlock (&thread_admin_mutex);
}
static void *
launch_thread (void *p)
{
really_launch (SCM_STACK_PTR (&p), (launch_data *) p);
return 0;
}
static SCM
create_thread (scm_t_catch_body body, void *body_data,
scm_t_catch_handler handler, void *handler_data,
SCM protects)
{
SCM thread;
/* Make new thread. The first thing the new thread will do is to
lock guile_mutex. Thus, we can safely complete its
initialization after creating it. While the new thread starts,
all its data is protected via all_threads.
*/
{
scm_t_thread th;
SCM root;
launch_data *data;
scm_thread *t;
int err;
/* Allocate thread locals. */
root = scm_make_root (scm_root->handle);
data = scm_malloc (sizeof (launch_data));
/* Make thread. */
thread = make_thread (protects);
data->thread = thread;
data->body = body;
data->body_data = body_data;
data->handler = handler;
data->handler_data = handler_data;
t = SCM_THREAD_DATA (thread);
/* must initialize root state pointer before the thread is linked
into all_threads */
t->root = SCM_ROOT_STATE (root);
/* disconnect from parent, to prevent remembering dead threads */
t->root->parent = SCM_BOOL_F;
/* start with an empty dynwind chain */
t->root->dynwinds = SCM_EOL;
/* In order to avoid the need of synchronization between parent
and child thread, we need to insert the child into all_threads
before creation. */
{
SCM new_threads = scm_cons (thread, SCM_BOOL_F); /* could cause GC */
scm_thread *parent = scm_i_leave_guile (); /* to prevent deadlock */
scm_i_plugin_mutex_lock (&thread_admin_mutex);
SCM_SETCDR (new_threads, all_threads);
all_threads = new_threads;
thread_count++;
scm_i_plugin_mutex_unlock (&thread_admin_mutex);
scm_remember_upto_here_1 (root);
scm_i_enter_guile (parent);
}
err = scm_i_plugin_thread_create (&th, 0, launch_thread, (void *) data);
if (err != 0)
{
scm_i_plugin_mutex_lock (&thread_admin_mutex);
all_threads = scm_delq_x (thread, all_threads);
((scm_thread *) SCM_THREAD_DATA(thread))->exited = 1;
thread_count--;
scm_i_plugin_mutex_unlock (&thread_admin_mutex);
}
if (err)
{
errno = err;
scm_syserror ("create-thread");
}
}
return thread;
}
SCM_DEFINE (scm_call_with_new_thread, "call-with-new-thread", 2, 0, 0,
(SCM thunk, SCM handler),
"Evaluate @code{(@var{thunk})} in a new thread, and new dynamic context, "
"returning a new thread object representing the thread. "
"If an error occurs during evaluation, call error-thunk, passing it an "
"error code describing the condition. "
"If this happens, the error-thunk is called outside the scope of the new "
"root -- it is called in the same dynamic context in which "
"with-new-thread was evaluated, but not in the callers thread. "
"All the evaluation rules for dynamic roots apply to threads.")
#define FUNC_NAME s_scm_call_with_new_thread
{
SCM_ASSERT (scm_is_true (scm_thunk_p (thunk)), thunk, SCM_ARG1, FUNC_NAME);
SCM_ASSERT (scm_is_true (scm_procedure_p (handler)), handler, SCM_ARG2,
FUNC_NAME);
return create_thread ((scm_t_catch_body) scm_call_0, thunk,
(scm_t_catch_handler) scm_apply_1, handler,
scm_cons (thunk, handler));
}
#undef FUNC_NAME
SCM_DEFINE (scm_yield, "yield", 0, 0, 0,
(),
"Move the calling thread to the end of the scheduling queue.")
#define FUNC_NAME s_scm_yield
{
return scm_from_bool (scm_thread_yield ());
}
#undef FUNC_NAME
SCM_DEFINE (scm_join_thread, "join-thread", 1, 0, 0,
(SCM thread),
"Suspend execution of the calling thread until the target @var{thread} "
"terminates, unless the target @var{thread} has already terminated. ")
#define FUNC_NAME s_scm_join_thread
{
scm_thread *t;
SCM res;
SCM_VALIDATE_THREAD (1, thread);
if (scm_is_eq (cur_thread, thread))
SCM_MISC_ERROR ("can not join the current thread", SCM_EOL);
t = SCM_THREAD_DATA (thread);
if (!t->exited)
{
scm_thread *c;
c = scm_i_leave_guile ();
while (!THREAD_INITIALIZED_P (t))
scm_i_plugin_thread_yield ();
scm_thread_join (t->thread, 0);
scm_i_enter_guile (c);
}
res = t->result;
t->result = SCM_BOOL_F;
return res;
}
#undef FUNC_NAME
/*** Fair mutexes */
/* We implement our own mutex type since we want them to be 'fair', we
want to do fancy things while waiting for them (like running
asyncs) and we want to support waiting on many things at once.
Also, we might add things that are nice for debugging.
*/
typedef struct fair_mutex {
/* the thread currently owning the mutex, or SCM_BOOL_F. */
scm_t_mutex lock;
int lockedp;
SCM owner;
/* how much the owner owns us. */
int level;
/* the threads waiting for this mutex. */
SCM waiting;
} fair_mutex;
static SCM
fair_mutex_mark (SCM mx)
{
fair_mutex *m = SCM_MUTEX_DATA (mx);
scm_gc_mark (m->owner);
return m->waiting;
}
SCM_DEFINE (scm_make_fair_mutex, "make-fair-mutex", 0, 0, 0,
(void),
"Create a new fair mutex object. ")
#define FUNC_NAME s_scm_make_fair_mutex
{
SCM mx = scm_make_smob (scm_tc16_fair_mutex);
fair_mutex *m = SCM_MUTEX_DATA (mx);
scm_i_plugin_mutex_init (&m->lock, &scm_i_plugin_mutex);
m->lockedp = 0;
m->owner = SCM_BOOL_F;
m->level = 0;
m->waiting = make_queue ();
return mx;
}
#undef FUNC_NAME
static int
fair_mutex_lock (fair_mutex *m)
{
scm_i_plugin_mutex_lock (&m->lock);
#if 0
/* Need to wait if another thread is just temporarily unlocking.
This is happens very seldom and only when the other thread is
between scm_mutex_unlock and scm_i_plugin_mutex_lock below. */
while (m->lockedp)
SCM_TICK;
m->lockedp = 1;
#endif
if (m->owner == SCM_BOOL_F)
m->owner = cur_thread;
else if (m->owner == cur_thread)
m->level++;
else
{
while (1)
{
SCM c = enqueue (m->waiting, cur_thread);
int err;
/* Note: It's important that m->lock is never locked for
any longer amount of time since that could prevent GC */
scm_i_plugin_mutex_unlock (&m->lock);
err = block ();
if (m->owner == cur_thread)
return 0;
scm_i_plugin_mutex_lock (&m->lock);
remqueue (m->waiting, c);
scm_i_plugin_mutex_unlock (&m->lock);
if (err)
return err;
SCM_ASYNC_TICK;
scm_i_plugin_mutex_lock (&m->lock);
}
}
scm_i_plugin_mutex_unlock (&m->lock);
return 0;
}
static int
fair_mutex_trylock (fair_mutex *m)
{
scm_i_plugin_mutex_lock (&m->lock);
if (m->owner == SCM_BOOL_F)
m->owner = cur_thread;
else if (m->owner == cur_thread)
m->level++;
else
{
scm_i_plugin_mutex_unlock (&m->lock);
return EBUSY;
}
scm_i_plugin_mutex_unlock (&m->lock);
return 0;
}
static int
fair_mutex_unlock (fair_mutex *m)
{
scm_i_plugin_mutex_lock (&m->lock);
if (m->owner != cur_thread)
{
scm_i_plugin_mutex_unlock (&m->lock);
return EPERM;
}
else if (m->level > 0)
m->level--;
else
{
SCM next = dequeue (m->waiting);
if (scm_is_true (next))
{
m->owner = next;
unblock (SCM_THREAD_DATA (next));
}
else
m->owner = SCM_BOOL_F;
}
scm_i_plugin_mutex_unlock (&m->lock);
return 0;
}
/*** Fair condition variables */
/* Like mutexes, we implement our own condition variables using the
primitives above.
*/
typedef struct fair_cond {
scm_t_mutex lock;
/* the threads waiting for this condition. */
SCM waiting;
} fair_cond;
static SCM
fair_cond_mark (SCM cv)
{
fair_cond *c = SCM_CONDVAR_DATA (cv);
return c->waiting;
}
SCM_DEFINE (scm_make_fair_condition_variable, "make-fair-condition-variable", 0, 0, 0,
(void),
"Make a new fair condition variable.")
#define FUNC_NAME s_scm_make_fair_condition_variable
{
SCM cv = scm_make_smob (scm_tc16_fair_condvar);
fair_cond *c = SCM_CONDVAR_DATA (cv);
scm_i_plugin_mutex_init (&c->lock, 0);
c->waiting = make_queue ();
return cv;
}
#undef FUNC_NAME
static int
fair_cond_timedwait (fair_cond *c,
fair_mutex *m,
const scm_t_timespec *waittime)
{
int err;
scm_i_plugin_mutex_lock (&c->lock);
while (1)
{
enqueue (c->waiting, cur_thread);
scm_i_plugin_mutex_unlock (&c->lock);
fair_mutex_unlock (m); /*fixme* - not thread safe */
if (waittime == NULL)
err = block ();
else
err = timed_block (waittime);
fair_mutex_lock (m);
if (err)
return err;
/* XXX - check whether we have been signalled. */
break;
}
return err;
}
static int
fair_cond_signal (fair_cond *c)
{
SCM th;
scm_i_plugin_mutex_lock (&c->lock);
if (scm_is_true (th = dequeue (c->waiting)))
unblock (SCM_THREAD_DATA (th));
scm_i_plugin_mutex_unlock (&c->lock);
return 0;
}
static int
fair_cond_broadcast (fair_cond *c)
{
SCM th;
scm_i_plugin_mutex_lock (&c->lock);
while (scm_is_true (th = dequeue (c->waiting)))
unblock (SCM_THREAD_DATA (th));
scm_i_plugin_mutex_unlock (&c->lock);
return 0;
}
/*** Mutexes */
SCM_DEFINE (scm_make_mutex, "make-mutex", 0, 0, 0,
(void),
"Create a new mutex object. ")
#define FUNC_NAME s_scm_make_mutex
{
SCM mx = scm_make_smob (scm_tc16_mutex);
scm_i_plugin_mutex_init (SCM_MUTEX_DATA (mx), &scm_i_plugin_mutex);
return mx;
}
#undef FUNC_NAME
/*fixme* change documentation */
SCM_DEFINE (scm_lock_mutex, "lock-mutex", 1, 0, 0,
(SCM mx),
"Lock @var{mutex}. If the mutex is already locked, the calling thread "
"blocks until the mutex becomes available. The function returns when "
"the calling thread owns the lock on @var{mutex}. Locking a mutex that "
"a thread already owns will succeed right away and will not block the "
"thread. That is, Guile's mutexes are @emph{recursive}. ")
#define FUNC_NAME s_scm_lock_mutex
{
int err;
SCM_VALIDATE_MUTEX (1, mx);
if (SCM_TYP16 (mx) == scm_tc16_fair_mutex)
err = fair_mutex_lock (SCM_MUTEX_DATA (mx));
else
{
scm_t_mutex *m = SCM_MUTEX_DATA (mx);
err = scm_mutex_lock (m);
}
if (err)
{
errno = err;
SCM_SYSERROR;
}
return SCM_BOOL_T;
}
#undef FUNC_NAME
SCM_DEFINE (scm_try_mutex, "try-mutex", 1, 0, 0,
(SCM mx),
"Try to lock @var{mutex}. If the mutex is already locked by someone "
"else, return @code{#f}. Else lock the mutex and return @code{#t}. ")
#define FUNC_NAME s_scm_try_mutex
{
int err;
SCM_VALIDATE_MUTEX (1, mx);
if (SCM_TYP16 (mx) == scm_tc16_fair_mutex)
err = fair_mutex_trylock (SCM_MUTEX_DATA (mx));
else
{
scm_t_mutex *m = SCM_MUTEX_DATA (mx);
err = scm_mutex_trylock (m);
}
if (err == EBUSY)
return SCM_BOOL_F;
if (err)
{
errno = err;
SCM_SYSERROR;
}
return SCM_BOOL_T;
}
#undef FUNC_NAME
SCM_DEFINE (scm_unlock_mutex, "unlock-mutex", 1, 0, 0,
(SCM mx),
"Unlocks @var{mutex} if the calling thread owns the lock on "
"@var{mutex}. Calling unlock-mutex on a mutex not owned by the current "
"thread results in undefined behaviour. Once a mutex has been unlocked, "
"one thread blocked on @var{mutex} is awakened and grabs the mutex "
"lock. Every call to @code{lock-mutex} by this thread must be matched "
"with a call to @code{unlock-mutex}. Only the last call to "
"@code{unlock-mutex} will actually unlock the mutex. ")
#define FUNC_NAME s_scm_unlock_mutex
{
int err;
SCM_VALIDATE_MUTEX (1, mx);
if (SCM_TYP16 (mx) == scm_tc16_fair_mutex)
{
err = fair_mutex_unlock (SCM_MUTEX_DATA (mx));
if (err == EPERM)
{
fair_mutex *m = SCM_MUTEX_DATA (mx);
if (m->owner != cur_thread)
{
if (m->owner == SCM_BOOL_F)
SCM_MISC_ERROR ("mutex not locked", SCM_EOL);
else
SCM_MISC_ERROR ("mutex not locked by this thread", SCM_EOL);
}
}
}
else
{
scm_t_mutex *m = SCM_MUTEX_DATA (mx);
err = scm_mutex_unlock (m);
}
if (err)
{
errno = err;
SCM_SYSERROR;
}
return SCM_BOOL_T;
}
#undef FUNC_NAME
/*** Condition variables */
SCM_DEFINE (scm_make_condition_variable, "make-condition-variable", 0, 0, 0,
(void),
"Make a new condition variable.")
#define FUNC_NAME s_scm_make_condition_variable
{
SCM cv = scm_make_smob (scm_tc16_condvar);
scm_i_plugin_cond_init (SCM_CONDVAR_DATA (cv), 0);
return cv;
}
#undef FUNC_NAME
SCM_DEFINE (scm_timed_wait_condition_variable, "wait-condition-variable", 2, 1, 0,
(SCM cv, SCM mx, SCM t),
"Wait until @var{cond-var} has been signalled. While waiting, "
"@var{mutex} is atomically unlocked (as with @code{unlock-mutex}) and "
"is locked again when this function returns. When @var{time} is given, "
"it specifies a point in time where the waiting should be aborted. It "
"can be either a integer as returned by @code{current-time} or a pair "
"as returned by @code{gettimeofday}. When the waiting is aborted the "
"mutex is locked and @code{#f} is returned. When the condition "
"variable is in fact signalled, the mutex is also locked and @code{#t} "
"is returned. ")
#define FUNC_NAME s_scm_timed_wait_condition_variable
{
scm_t_timespec waittime;
int err;
SCM_VALIDATE_CONDVAR (1, cv);
SCM_VALIDATE_MUTEX (2, mx);
if (!((SCM_TYP16 (cv) == scm_tc16_condvar
&& SCM_TYP16 (mx) == scm_tc16_mutex)
|| (SCM_TYP16 (cv) == scm_tc16_fair_condvar
&& SCM_TYP16 (mx) == scm_tc16_fair_mutex)))
SCM_MISC_ERROR ("Condition variable and mutex are of different kinds.",
SCM_EOL);
if (!SCM_UNBNDP (t))
{
if (SCM_CONSP (t))
{
SCM_VALIDATE_UINT_COPY (3, SCM_CAR (t), waittime.tv_sec);
SCM_VALIDATE_UINT_COPY (3, SCM_CDR (t), waittime.tv_nsec);
waittime.tv_nsec *= 1000;
}
else
{
SCM_VALIDATE_UINT_COPY (3, t, waittime.tv_sec);
waittime.tv_nsec = 0;
}
}
if (SCM_TYP16 (cv) == scm_tc16_fair_condvar)
err = fair_cond_timedwait (SCM_CONDVAR_DATA (cv),
SCM_MUTEX_DATA (mx),
SCM_UNBNDP (t) ? NULL : &waittime);
else
{
scm_t_cond *c = SCM_CONDVAR_DATA (cv);
scm_t_mutex *m = SCM_MUTEX_DATA (mx);
if (SCM_UNBNDP (t))
err = scm_cond_wait (c, m);
else
err = scm_cond_timedwait (c, m, &waittime);
}
if (err)
{
if (err == ETIMEDOUT)
return SCM_BOOL_F;
errno = err;
SCM_SYSERROR;
}
return SCM_BOOL_T;
}
#undef FUNC_NAME
SCM_DEFINE (scm_signal_condition_variable, "signal-condition-variable", 1, 0, 0,
(SCM cv),
"Wake up one thread that is waiting for @var{cv}")
#define FUNC_NAME s_scm_signal_condition_variable
{
SCM_VALIDATE_CONDVAR (1, cv);
if (SCM_TYP16 (cv) == scm_tc16_fair_condvar)
fair_cond_signal (SCM_CONDVAR_DATA (cv));
else
{
scm_t_cond *c = SCM_CONDVAR_DATA (cv);
scm_cond_signal (c);
}
return SCM_BOOL_T;
}
#undef FUNC_NAME
SCM_DEFINE (scm_broadcast_condition_variable, "broadcast-condition-variable", 1, 0, 0,
(SCM cv),
"Wake up all threads that are waiting for @var{cv}. ")
#define FUNC_NAME s_scm_broadcast_condition_variable
{
SCM_VALIDATE_CONDVAR (1, cv);
if (SCM_TYP16 (cv) == scm_tc16_fair_condvar)
fair_cond_broadcast (SCM_CONDVAR_DATA (cv));
else
{
scm_t_cond *c = SCM_CONDVAR_DATA (cv);
scm_cond_broadcast (c);
}
return SCM_BOOL_T;
}
#undef FUNC_NAME
/*** Marking stacks */
/* XXX - what to do with this? Do we need to handle this for blocked
threads as well?
*/
#ifdef __ia64__
# define SCM_MARK_BACKING_STORE() do { \
ucontext_t ctx; \
SCM_STACKITEM * top, * bot; \
getcontext (&ctx); \
scm_mark_locations ((SCM_STACKITEM *) &ctx.uc_mcontext, \
((size_t) (sizeof (SCM_STACKITEM) - 1 + sizeof ctx.uc_mcontext) \
/ sizeof (SCM_STACKITEM))); \
bot = (SCM_STACKITEM *) __libc_ia64_register_backing_store_base; \
top = (SCM_STACKITEM *) ctx.uc_mcontext.sc_ar_bsp; \
scm_mark_locations (bot, top - bot); } while (0)
#else
# define SCM_MARK_BACKING_STORE()
#endif
void
scm_threads_mark_stacks (void)
{
volatile SCM c;
for (c = all_threads; !SCM_NULLP (c); c = SCM_CDR (c))
{
scm_thread *t = SCM_THREAD_DATA (SCM_CAR (c));
if (!THREAD_INITIALIZED_P (t))
{
/* Not fully initialized yet. */
continue;
}
if (t->top == NULL)
{
/* Thread has not been suspended, which should never happen.
*/
abort ();
}
#if SCM_STACK_GROWS_UP
long stack_len = t->top - t->base;
scm_mark_locations (t->base, stack_len);
#else
long stack_len = t->base - t->top;
scm_mark_locations (t->top, stack_len);
#endif
scm_mark_locations ((SCM_STACKITEM *) t->regs,
((size_t) sizeof(t->regs)
/ sizeof (SCM_STACKITEM)));
}
}
/*** Select */
int
scm_internal_select (int nfds,
SELECT_TYPE *readfds,
SELECT_TYPE *writefds,
SELECT_TYPE *exceptfds,
struct timeval *timeout)
{
int res, eno;
scm_thread *c = scm_i_leave_guile ();
res = scm_i_plugin_select (nfds, readfds, writefds, exceptfds, timeout);
eno = errno;
scm_i_enter_guile (c);
SCM_ASYNC_TICK;
errno = eno;
return res;
}
/* Low-level C API */
SCM
scm_spawn_thread (scm_t_catch_body body, void *body_data,
scm_t_catch_handler handler, void *handler_data)
{
return create_thread (body, body_data, handler, handler_data, SCM_BOOL_F);
}
scm_t_thread
scm_c_scm2thread (SCM thread)
{
return SCM_THREAD_DATA (thread)->thread;
}
int
scm_mutex_lock (scm_t_mutex *m)
{
scm_thread *t = scm_i_leave_guile ();
int res = scm_i_plugin_mutex_lock (m);
scm_i_enter_guile (t);
return res;
}
scm_t_rec_mutex *
scm_make_rec_mutex ()
{
scm_t_rec_mutex *m = scm_malloc (sizeof (scm_t_rec_mutex));
scm_i_plugin_rec_mutex_init (m, &scm_i_plugin_rec_mutex);
return m;
}
void
scm_rec_mutex_free (scm_t_rec_mutex *m)
{
scm_i_plugin_rec_mutex_destroy (m);
free (m);
}
int
scm_rec_mutex_lock (scm_t_rec_mutex *m)
{
scm_thread *t = scm_i_leave_guile ();
int res = scm_i_plugin_rec_mutex_lock (m);
scm_i_enter_guile (t);
return res;
}
int
scm_cond_wait (scm_t_cond *c, scm_t_mutex *m)
{
scm_thread *t = scm_i_leave_guile ();
scm_i_plugin_cond_wait (c, m);
scm_i_enter_guile (t);
return 0;
}
int
scm_cond_timedwait (scm_t_cond *c, scm_t_mutex *m, const scm_t_timespec *wt)
{
scm_thread *t = scm_i_leave_guile ();
int res = scm_i_plugin_cond_timedwait (c, m, wt);
scm_i_enter_guile (t);
return res;
}
void *
scm_getspecific (scm_t_key k)
{
return scm_i_plugin_getspecific (k);
}
int
scm_setspecific (scm_t_key k, void *s)
{
return scm_i_plugin_setspecific (k, s);
}
void
scm_enter_guile ()
{
scm_i_enter_guile (SCM_CURRENT_THREAD);
}
void
scm_leave_guile ()
{
scm_i_leave_guile ();
}
unsigned long
scm_thread_usleep (unsigned long usecs)
{
struct timeval tv;
tv.tv_usec = usecs % 1000000;
tv.tv_sec = usecs / 1000000;
scm_internal_select (0, NULL, NULL, NULL, &tv);
return tv.tv_usec + tv.tv_sec*1000000;
}
unsigned long
scm_thread_sleep (unsigned long secs)
{
struct timeval tv;
tv.tv_usec = 0;
tv.tv_sec = secs;
scm_internal_select (0, NULL, NULL, NULL, &tv);
return tv.tv_sec;
}
/*** Misc */
SCM_DEFINE (scm_current_thread, "current-thread", 0, 0, 0,
(void),
"Return the thread that called this function.")
#define FUNC_NAME s_scm_current_thread
{
return cur_thread;
}
#undef FUNC_NAME
SCM_DEFINE (scm_all_threads, "all-threads", 0, 0, 0,
(void),
"Return a list of all threads.")
#define FUNC_NAME s_scm_all_threads
{
return scm_list_copy (all_threads);
}
#undef FUNC_NAME
scm_root_state *
scm_i_thread_root (SCM thread)
{
return ((scm_thread *) SCM_THREAD_DATA (thread))->root;
}
SCM_DEFINE (scm_thread_exited_p, "thread-exited?", 1, 0, 0,
(SCM thread),
"Return @code{#t} iff @var{thread} has exited.\n")
#define FUNC_NAME s_scm_thread_exited_p
{
return scm_from_bool (scm_c_thread_exited_p (thread));
}
#undef FUNC_NAME
int
scm_c_thread_exited_p (SCM thread)
#define FUNC_NAME s_scm_thread_exited_p
{
scm_thread *t;
SCM_VALIDATE_THREAD (1, thread);
t = SCM_THREAD_DATA (thread);
return t->exited;
}
#undef FUNC_NAME
static scm_t_cond wake_up_cond;
int scm_i_thread_go_to_sleep;
static int threads_initialized_p = 0;
void
scm_i_thread_put_to_sleep ()
{
if (threads_initialized_p)
{
SCM threads;
/* We leave Guile completely before locking the
thread_admin_mutex. This ensures that other threads can put
us to sleep while we block on that mutex.
*/
scm_i_leave_guile ();
scm_i_plugin_mutex_lock (&thread_admin_mutex);
threads = all_threads;
/* Signal all threads to go to sleep */
scm_i_thread_go_to_sleep = 1;
for (; !SCM_NULLP (threads); threads = SCM_CDR (threads))
{
scm_thread *t = SCM_THREAD_DATA (SCM_CAR (threads));
scm_i_plugin_mutex_lock (&t->heap_mutex);
}
scm_i_thread_go_to_sleep = 0;
}
}
void
scm_i_thread_invalidate_freelists ()
{
/* Don't need to lock thread_admin_mutex here since we are single threaded */
SCM threads = all_threads;
for (; !SCM_NULLP (threads); threads = SCM_CDR (threads))
if (SCM_CAR (threads) != cur_thread)
{
scm_thread *t = SCM_THREAD_DATA (SCM_CAR (threads));
t->clear_freelists_p = 1;
}
}
void
scm_i_thread_wake_up ()
{
if (threads_initialized_p)
{
SCM threads;
threads = all_threads;
scm_i_plugin_cond_broadcast (&wake_up_cond);
for (; !SCM_NULLP (threads); threads = SCM_CDR (threads))
{
scm_thread *t = SCM_THREAD_DATA (SCM_CAR (threads));
scm_i_plugin_mutex_unlock (&t->heap_mutex);
}
scm_i_plugin_mutex_unlock (&thread_admin_mutex);
scm_i_enter_guile (SCM_CURRENT_THREAD);
}
}
void
scm_i_thread_sleep_for_gc ()
{
scm_thread *t;
t = suspend ();
scm_i_plugin_cond_wait (&wake_up_cond, &t->heap_mutex);
resume (t);
}
scm_t_mutex scm_i_critical_section_mutex;
scm_t_rec_mutex scm_i_defer_mutex;
#if SCM_USE_PTHREAD_THREADS
# include "libguile/pthread-threads.c"
#endif
#include "libguile/threads-plugin.c"
/*** Initialization */
void
scm_threads_prehistory ()
{
scm_thread *t;
#if SCM_USE_PTHREAD_THREADS
/* Must be called before any initialization of a mutex. */
scm_init_pthread_threads ();
#endif
scm_i_plugin_mutex_init (&thread_admin_mutex, &scm_i_plugin_mutex);
scm_i_plugin_cond_init (&wake_up_cond, 0);
scm_i_plugin_mutex_init (&scm_i_critical_section_mutex, &scm_i_plugin_mutex);
thread_count = 1;
scm_i_plugin_key_create (&scm_i_thread_key, 0);
scm_i_plugin_key_create (&scm_i_root_state_key, 0);
scm_i_plugin_rec_mutex_init (&scm_i_defer_mutex, &scm_i_plugin_rec_mutex);
/* Allocate a fake thread object to be used during bootup. */
t = malloc (sizeof (scm_thread));
t->base = NULL;
t->clear_freelists_p = 0;
scm_i_plugin_mutex_init (&t->heap_mutex, &scm_i_plugin_mutex);
scm_setspecific (scm_i_thread_key, t);
scm_i_enter_guile (t);
}
scm_t_bits scm_tc16_thread;
scm_t_bits scm_tc16_future;
scm_t_bits scm_tc16_mutex;
scm_t_bits scm_tc16_fair_mutex;
scm_t_bits scm_tc16_condvar;
scm_t_bits scm_tc16_fair_condvar;
void
scm_init_threads (SCM_STACKITEM *base)
{
SCM thread;
scm_tc16_thread = scm_make_smob_type ("thread", sizeof (scm_thread));
scm_tc16_mutex = scm_make_smob_type ("mutex", sizeof (scm_t_mutex));
scm_tc16_fair_mutex = scm_make_smob_type ("fair-mutex",
sizeof (fair_mutex));
scm_tc16_condvar = scm_make_smob_type ("condition-variable",
sizeof (scm_t_cond));
scm_tc16_fair_condvar = scm_make_smob_type ("fair-condition-variable",
sizeof (fair_cond));
thread = make_thread (SCM_BOOL_F);
/* Replace initial fake thread with a real thread object */
free (SCM_CURRENT_THREAD);
scm_setspecific (scm_i_thread_key, SCM_THREAD_DATA (thread));
scm_i_enter_guile (SCM_CURRENT_THREAD);
/* root is set later from init.c */
init_thread_creatant (thread, base);
thread_count = 1;
scm_gc_register_root (&all_threads);
all_threads = scm_cons (thread, SCM_EOL);
scm_set_smob_mark (scm_tc16_thread, thread_mark);
scm_set_smob_print (scm_tc16_thread, thread_print);
scm_set_smob_free (scm_tc16_thread, thread_free);
scm_set_smob_mark (scm_tc16_fair_mutex, fair_mutex_mark);
scm_set_smob_mark (scm_tc16_fair_condvar, fair_cond_mark);
threads_initialized_p = 1;
}
/* scm_i_misc_mutex is intended for miscellaneous uses, to protect
operations which are non-reentrant or non-thread-safe but which are
either not important enough or not used often enough to deserve their own
private mutex. */
SCM_GLOBAL_MUTEX (scm_i_misc_mutex);
void
scm_init_thread_procs ()
{
#include "libguile/threads.x"
}
/* XXX */
void
scm_init_iselect ()
{
}
/*
Local Variables:
c-file-style: "gnu"
End:
*/
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