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Add MSG_process_join [#13601]
[simgrid.git]
/
src
/
simix
/
smx_user.c
diff --git
a/src/simix/smx_user.c
b/src/simix/smx_user.c
index
c6da787
..
453c741
100644
(file)
--- a/
src/simix/smx_user.c
+++ b/
src/simix/smx_user.c
@@
-239,7
+239,7
@@
smx_action_t simcall_host_execute(const char *name, smx_host_t host,
/* checking for infinite values */
xbt_assert(isfinite(computation_amount), "computation_amount is not finite!");
xbt_assert(isfinite(priority), "priority is not finite!");
/* checking for infinite values */
xbt_assert(isfinite(computation_amount), "computation_amount is not finite!");
xbt_assert(isfinite(priority), "priority is not finite!");
-
+
return simcall_BODY_host_execute(name, host, computation_amount, priority, bound, affinity_mask);
}
return simcall_BODY_host_execute(name, host, computation_amount, priority, bound, affinity_mask);
}
@@
-271,14
+271,14
@@
smx_action_t simcall_host_parallel_execute(const char *name,
for (i = 0 ; i < host_nb ; ++i) {
xbt_assert(isfinite(computation_amount[i]), "computation_amount[%d] is not finite!", i);
for (j = 0 ; j < host_nb ; ++j) {
for (i = 0 ; i < host_nb ; ++i) {
xbt_assert(isfinite(computation_amount[i]), "computation_amount[%d] is not finite!", i);
for (j = 0 ; j < host_nb ; ++j) {
- xbt_assert(isfinite(communication_amount[i + host_nb * j]),
+ xbt_assert(isfinite(communication_amount[i + host_nb * j]),
"communication_amount[%d+%d*%d] is not finite!", i, host_nb, j);
"communication_amount[%d+%d*%d] is not finite!", i, host_nb, j);
- }
- }
-
+ }
+ }
+
xbt_assert(isfinite(amount), "amount is not finite!");
xbt_assert(isfinite(rate), "rate is not finite!");
xbt_assert(isfinite(amount), "amount is not finite!");
xbt_assert(isfinite(rate), "rate is not finite!");
-
+
return simcall_BODY_host_parallel_execute(name, host_nb, host_list,
computation_amount,
communication_amount,
return simcall_BODY_host_parallel_execute(name, host_nb, host_list,
computation_amount,
communication_amount,
@@
-346,7
+346,7
@@
void simcall_host_execution_set_priority(smx_action_t execution, double priority
{
/* checking for infinite values */
xbt_assert(isfinite(priority), "priority is not finite!");
{
/* checking for infinite values */
xbt_assert(isfinite(priority), "priority is not finite!");
-
+
simcall_BODY_host_execution_set_priority(execution, priority);
}
simcall_BODY_host_execution_set_priority(execution, priority);
}
@@
-629,6
+629,11
@@
void simcall_process_change_host(smx_process_t process, smx_host_t dest)
simcall_BODY_process_change_host(process, dest);
}
simcall_BODY_process_change_host(process, dest);
}
+void simcall_process_join(smx_process_t process, double timeout)
+{
+ simcall_BODY_process_join(process, timeout);
+}
+
/**
* \ingroup simix_process_management
* \brief Suspends a process.
/**
* \ingroup simix_process_management
* \brief Suspends a process.
@@
-814,7
+819,7
@@
xbt_dict_t simcall_process_get_properties(smx_process_t process)
* \brief Add an on_exit function
* Add an on_exit function which will be executed when the process exits/is killed.
*/
* \brief Add an on_exit function
* Add an on_exit function which will be executed when the process exits/is killed.
*/
-XBT_PUBLIC(void) simcall_process_on_exit(smx_process_t process, int_f_pvoid_t fun, void *data)
+XBT_PUBLIC(void) simcall_process_on_exit(smx_process_t process, int_f_pvoid_
pvoid_
t fun, void *data)
{
simcall_BODY_process_on_exit(process, fun, data);
}
{
simcall_BODY_process_on_exit(process, fun, data);
}
@@
-937,7
+942,7
@@
void simcall_comm_send(smx_rdv_t rdv, double task_size, double rate,
xbt_assert(isfinite(task_size), "task_size is not finite!");
xbt_assert(isfinite(rate), "rate is not finite!");
xbt_assert(isfinite(timeout), "timeout is not finite!");
xbt_assert(isfinite(task_size), "task_size is not finite!");
xbt_assert(isfinite(rate), "rate is not finite!");
xbt_assert(isfinite(timeout), "timeout is not finite!");
-
+
xbt_assert(rdv, "No rendez-vous point defined for send");
if (MC_is_active()) {
xbt_assert(rdv, "No rendez-vous point defined for send");
if (MC_is_active()) {
@@
-967,7
+972,7
@@
smx_action_t simcall_comm_isend(smx_rdv_t rdv, double task_size, double rate,
/* checking for infinite values */
xbt_assert(isfinite(task_size), "task_size is not finite!");
xbt_assert(isfinite(rate), "rate is not finite!");
/* checking for infinite values */
xbt_assert(isfinite(task_size), "task_size is not finite!");
xbt_assert(isfinite(rate), "rate is not finite!");
-
+
xbt_assert(rdv, "No rendez-vous point defined for isend");
return simcall_BODY_comm_isend(rdv, task_size, rate, src_buff,
xbt_assert(rdv, "No rendez-vous point defined for isend");
return simcall_BODY_comm_isend(rdv, task_size, rate, src_buff,
@@
-1134,7
+1139,7
@@
smx_process_t simcall_comm_get_src_proc(smx_action_t comm)
*/
smx_process_t simcall_comm_get_dst_proc(smx_action_t comm)
{
*/
smx_process_t simcall_comm_get_dst_proc(smx_action_t comm)
{
- return simcall_BODY_comm_get_dst_proc(comm);
+ return simcall_BODY_comm_get_dst_proc(comm);
}
#ifdef HAVE_LATENCY_BOUND_TRACKING
}
#ifdef HAVE_LATENCY_BOUND_TRACKING
@@
-1172,7
+1177,7
@@
void simcall_mutex_destroy(smx_mutex_t mutex)
*/
void simcall_mutex_lock(smx_mutex_t mutex)
{
*/
void simcall_mutex_lock(smx_mutex_t mutex)
{
- simcall_BODY_mutex_lock(mutex);
+ simcall_BODY_mutex_lock(mutex);
}
/**
}
/**
@@
-1181,7
+1186,7
@@
void simcall_mutex_lock(smx_mutex_t mutex)
*/
int simcall_mutex_trylock(smx_mutex_t mutex)
{
*/
int simcall_mutex_trylock(smx_mutex_t mutex)
{
- return simcall_BODY_mutex_trylock(mutex);
+ return simcall_BODY_mutex_trylock(mutex);
}
/**
}
/**
@@
-1190,7
+1195,7
@@
int simcall_mutex_trylock(smx_mutex_t mutex)
*/
void simcall_mutex_unlock(smx_mutex_t mutex)
{
*/
void simcall_mutex_unlock(smx_mutex_t mutex)
{
- simcall_BODY_mutex_unlock(mutex);
+ simcall_BODY_mutex_unlock(mutex);
}
/**
}
/**
@@
-1256,7
+1261,7
@@
void simcall_cond_broadcast(smx_cond_t cond)
*/
smx_sem_t simcall_sem_init(int capacity)
{
*/
smx_sem_t simcall_sem_init(int capacity)
{
- return simcall_BODY_sem_init(capacity);
+ return simcall_BODY_sem_init(capacity);
}
/**
}
/**
@@
-1274,7
+1279,7
@@
void simcall_sem_destroy(smx_sem_t sem)
*/
void simcall_sem_release(smx_sem_t sem)
{
*/
void simcall_sem_release(smx_sem_t sem)
{
- simcall_BODY_sem_release(sem);
+ simcall_BODY_sem_release(sem);
}
/**
}
/**
@@
-1336,18
+1341,18
@@
sg_size_t simcall_file_write(smx_file_t fd, sg_size_t size, smx_host_t host)
* \ingroup simix_file_management
* \brief
*/
* \ingroup simix_file_management
* \brief
*/
-smx_file_t simcall_file_open(const char* fullpath)
+smx_file_t simcall_file_open(const char* fullpath
, smx_host_t host
)
{
{
- return simcall_BODY_file_open(fullpath);
+ return simcall_BODY_file_open(fullpath
, host
);
}
/**
* \ingroup simix_file_management
*
*/
}
/**
* \ingroup simix_file_management
*
*/
-int simcall_file_close(smx_file_t fd)
+int simcall_file_close(smx_file_t fd
, smx_host_t host
)
{
{
- return simcall_BODY_file_close(fd);
+ return simcall_BODY_file_close(fd
, host
);
}
/**
}
/**
@@
-1359,14
+1364,6
@@
int simcall_file_unlink(smx_file_t fd)
return simcall_BODY_file_unlink(fd);
}
return simcall_BODY_file_unlink(fd);
}
-/**
- * \ingroup simix_file_management
- *
- */
-xbt_dict_t simcall_file_ls(const char* mount, const char* path)
-{
- return simcall_BODY_file_ls(mount, path);
-}
/**
* \ingroup simix_file_management
*
/**
* \ingroup simix_file_management
*
@@
-1410,34
+1407,24
@@
int simcall_file_move(smx_file_t fd, const char* fullpath)
return simcall_BODY_file_move(fd, fullpath);
}
return simcall_BODY_file_move(fd, fullpath);
}
-/**
- * \ingroup simix_file_management
- * \brief Copy a file to another location on a remote host.
- *
- */
-int simcall_file_rcopy(smx_file_t fd, smx_host_t host, const char* fullpath)
-{
- return simcall_BODY_file_rcopy(fd, host, fullpath);
-}
-
/**
* \ingroup simix_storage_management
* \brief Returns the free space size on a given storage element.
/**
* \ingroup simix_storage_management
* \brief Returns the free space size on a given storage element.
- * \param storage
nam
e
+ * \param storage
a storag
e
* \return Return the free space size on a given storage element (as sg_size_t)
*/
* \return Return the free space size on a given storage element (as sg_size_t)
*/
-sg_size_t simcall_storage_get_free_size (
const char* nam
e){
- return simcall_BODY_storage_get_free_size(
nam
e);
+sg_size_t simcall_storage_get_free_size (
smx_storage_t storag
e){
+ return simcall_BODY_storage_get_free_size(
storag
e);
}
/**
* \ingroup simix_storage_management
* \brief Returns the used space size on a given storage element.
}
/**
* \ingroup simix_storage_management
* \brief Returns the used space size on a given storage element.
- * \param storage
nam
e
+ * \param storage
a storag
e
* \return Return the used space size on a given storage element (as sg_size_t)
*/
* \return Return the used space size on a given storage element (as sg_size_t)
*/
-sg_size_t simcall_storage_get_used_size (
const char* nam
e){
- return simcall_BODY_storage_get_used_size(
nam
e);
+sg_size_t simcall_storage_get_used_size (
smx_storage_t storag
e){
+ return simcall_BODY_storage_get_used_size(
storag
e);
}
/**
}
/**
@@
-1493,7
+1480,7
@@
void *simcall_mc_snapshot(void)
return simcall_BODY_mc_snapshot();
}
return simcall_BODY_mc_snapshot();
}
-int simcall_mc_compare_snapshots(void *s1, void *s2){
+int simcall_mc_compare_snapshots(void *s1, void *s2){
return simcall_BODY_mc_compare_snapshots(s1, s2);
}
return simcall_BODY_mc_compare_snapshots(s1, s2);
}