* \param flops_amount amount Computation amount (in flops)
* \param priority computation priority
* \param bound
- * \param affinity_mask
* \return A new SIMIX execution synchronization
*/
-smx_synchro_t simcall_execution_start(const char *name,
+smx_activity_t simcall_execution_start(const char *name,
double flops_amount,
- double priority, double bound, unsigned long affinity_mask)
+ double priority, double bound)
{
/* checking for infinite values */
xbt_assert(std::isfinite(flops_amount), "flops_amount is not finite!");
xbt_assert(std::isfinite(priority), "priority is not finite!");
- return simcall_BODY_execution_start(name, flops_amount, priority, bound, affinity_mask);
+ return simcall_BODY_execution_start(name, flops_amount, priority, bound);
}
/**
* \param rate the SURF action rate
* \return A new SIMIX execution synchronization
*/
-smx_synchro_t simcall_execution_parallel_start(const char *name,
+smx_activity_t simcall_execution_parallel_start(const char *name,
int host_nb,
sg_host_t *host_list,
double *flops_amount,
* This functions stops the execution. It calls a surf function.
* \param execution The execution synchro to cancel
*/
-void simcall_execution_cancel(smx_synchro_t execution)
+void simcall_execution_cancel(smx_activity_t execution)
{
simcall_BODY_execution_cancel(execution);
}
* \param execution The execution synchro
* \param priority The new priority
*/
-void simcall_execution_set_priority(smx_synchro_t execution, double priority)
+void simcall_execution_set_priority(smx_activity_t execution, double priority)
{
/* checking for infinite values */
xbt_assert(std::isfinite(priority), "priority is not finite!");
* \param execution The execution synchro
* \param bound The new bound
*/
-void simcall_execution_set_bound(smx_synchro_t execution, double bound)
+void simcall_execution_set_bound(smx_activity_t execution, double bound)
{
simcall_BODY_execution_set_bound(execution, bound);
}
-/**
- * \ingroup simix_process_management
- * \brief Changes the CPU affinity of an execution synchro.
- *
- * This functions changes the CPU affinity of an execution synchro. See taskset(1) on Linux.
- * \param execution The execution synchro
- * \param host Host
- * \param mask Affinity mask
- */
-void simcall_execution_set_affinity(smx_synchro_t execution, sg_host_t host, unsigned long mask)
-{
- simcall_BODY_execution_set_affinity(execution, host, mask);
-}
-
/**
* \ingroup simix_host_management
* \brief Waits for the completion of an execution synchro and destroy it.
*
* \param execution The execution synchro
*/
-e_smx_state_t simcall_execution_wait(smx_synchro_t execution)
+e_smx_state_t simcall_execution_wait(smx_activity_t execution)
{
return (e_smx_state_t) simcall_BODY_execution_wait(execution);
}
simgrid::simix::kernelImmediate(std::bind(SIMIX_vm_set_bound, vm, bound));
}
-void simcall_vm_set_affinity(sg_host_t vm, sg_host_t pm, unsigned long mask)
-{
- simgrid::simix::kernelImmediate(std::bind(SIMIX_vm_set_affinity, vm, pm, mask));
-}
-
/**
* \ingroup simix_vm_management
* \brief Migrate the given VM to the given physical host
* \ingroup simix_vm_management
* \brief Encompassing simcall to prevent the removal of the src or the dst node at the end of a VM migration
* The simcall actually invokes the following calls:
- * simcall_vm_set_affinity(vm, src_pm, 0);
* simcall_vm_migrate(vm, dst_pm);
* simcall_vm_resume(vm);
*
*
* Maestro internal process is not counted, only user code processes are
*/
-int simcall_process_count(void)
+int simcall_process_count()
{
return simgrid::simix::kernelImmediate(SIMIX_process_count);
}
-/**
- * \ingroup simix_process_management
- * \brief Return the PID of a #smx_process_t.
- * \param process a SIMIX process
- * \return the PID of this process
- */
-int simcall_process_get_PID(smx_process_t process)
-{
- return SIMIX_process_get_PID(process);
-}
-
-/**
- * \ingroup simix_process_management
- * \brief Return the parent PID of a #smx_process_t.
- * \param process a SIMIX process
- * \return the PID of this process parenrt
- */
-int simcall_process_get_PPID(smx_process_t process)
-{
- return SIMIX_process_get_PPID(process);
-}
-
/**
* \ingroup simix_process_management
* \brief Return the user data of a #smx_process_t.
*/
void simcall_comm_send(smx_process_t sender, smx_mailbox_t mbox, double task_size, double rate,
void *src_buff, size_t src_buff_size,
- int (*match_fun)(void *, void *, smx_synchro_t),
- void (*copy_data_fun)(smx_synchro_t, void*, size_t), void *data,
+ int (*match_fun)(void *, void *, smx_activity_t),
+ void (*copy_data_fun)(smx_activity_t, void*, size_t), void *data,
double timeout)
{
/* checking for infinite values */
if (MC_is_active() || MC_record_replay_is_active()) {
/* the model-checker wants two separate simcalls */
- smx_synchro_t comm = nullptr; /* MC needs the comm to be set to nullptr during the simcall */
+ smx_activity_t comm = nullptr; /* MC needs the comm to be set to nullptr during the simcall */
comm = simcall_comm_isend(sender, mbox, task_size, rate,
src_buff, src_buff_size, match_fun, nullptr, copy_data_fun, data, 0);
simcall_comm_wait(comm, timeout);
/**
* \ingroup simix_comm_management
*/
-smx_synchro_t simcall_comm_isend(smx_process_t sender, smx_mailbox_t mbox, double task_size, double rate,
+smx_activity_t simcall_comm_isend(smx_process_t sender, smx_mailbox_t mbox, double task_size, double rate,
void *src_buff, size_t src_buff_size,
- int (*match_fun)(void *, void *, smx_synchro_t),
+ int (*match_fun)(void *, void *, smx_activity_t),
void (*clean_fun)(void *),
- void (*copy_data_fun)(smx_synchro_t, void*, size_t),
+ void (*copy_data_fun)(smx_activity_t, void*, size_t),
void *data,
int detached)
{
* \ingroup simix_comm_management
*/
void simcall_comm_recv(smx_process_t receiver, smx_mailbox_t mbox, void *dst_buff, size_t * dst_buff_size,
- int (*match_fun)(void *, void *, smx_synchro_t),
- void (*copy_data_fun)(smx_synchro_t, void*, size_t),
+ int (*match_fun)(void *, void *, smx_activity_t),
+ void (*copy_data_fun)(smx_activity_t, void*, size_t),
void *data, double timeout, double rate)
{
xbt_assert(std::isfinite(timeout), "timeout is not finite!");
if (MC_is_active() || MC_record_replay_is_active()) {
/* the model-checker wants two separate simcalls */
- smx_synchro_t comm = nullptr; /* MC needs the comm to be set to nullptr during the simcall */
+ smx_activity_t comm = nullptr; /* MC needs the comm to be set to nullptr during the simcall */
comm = simcall_comm_irecv(receiver, mbox, dst_buff, dst_buff_size,
match_fun, copy_data_fun, data, rate);
simcall_comm_wait(comm, timeout);
/**
* \ingroup simix_comm_management
*/
-smx_synchro_t simcall_comm_irecv(smx_process_t receiver, smx_mailbox_t mbox, void *dst_buff, size_t *dst_buff_size,
- int (*match_fun)(void *, void *, smx_synchro_t),
- void (*copy_data_fun)(smx_synchro_t, void*, size_t),
+smx_activity_t simcall_comm_irecv(smx_process_t receiver, smx_mailbox_t mbox, void *dst_buff, size_t *dst_buff_size,
+ int (*match_fun)(void *, void *, smx_activity_t),
+ void (*copy_data_fun)(smx_activity_t, void*, size_t),
void *data, double rate)
{
xbt_assert(mbox, "No rendez-vous point defined for irecv");
/**
* \ingroup simix_comm_management
*/
-smx_synchro_t simcall_comm_iprobe(smx_mailbox_t mbox, int type, int src, int tag,
- int (*match_fun)(void *, void *, smx_synchro_t), void *data)
+smx_activity_t simcall_comm_iprobe(smx_mailbox_t mbox, int type, int src, int tag,
+ int (*match_fun)(void *, void *, smx_activity_t), void *data)
{
xbt_assert(mbox, "No rendez-vous point defined for iprobe");
/**
* \ingroup simix_comm_management
*/
-void simcall_comm_cancel(smx_synchro_t synchro)
+void simcall_comm_cancel(smx_activity_t synchro)
{
simgrid::simix::kernelImmediate([synchro]{
simgrid::kernel::activity::Comm *comm = static_cast<simgrid::kernel::activity::Comm*>(synchro);
/**
* \ingroup simix_comm_management
*/
-int simcall_comm_testany(smx_synchro_t* comms, size_t count)
+int simcall_comm_testany(smx_activity_t* comms, size_t count)
{
if (count == 0)
return -1;
/**
* \ingroup simix_comm_management
*/
-void simcall_comm_wait(smx_synchro_t comm, double timeout)
+void simcall_comm_wait(smx_activity_t comm, double timeout)
{
xbt_assert(std::isfinite(timeout), "timeout is not finite!");
simcall_BODY_comm_wait(comm, timeout);
* \param execution The execution synchro
* \param category The tracing category
*/
-void simcall_set_category(smx_synchro_t synchro, const char *category)
+void simcall_set_category(smx_activity_t synchro, const char *category)
{
if (category == nullptr) {
return;
* \ingroup simix_comm_management
*
*/
-int simcall_comm_test(smx_synchro_t comm)
+int simcall_comm_test(smx_activity_t comm)
{
return simcall_BODY_comm_test(comm);
}
* \ingroup simix_synchro_management
*
*/
-smx_mutex_t simcall_mutex_init(void)
+smx_mutex_t simcall_mutex_init()
{
if(!simix_global) {
fprintf(stderr,"You must run MSG_init before using MSG\n"); // We can't use xbt_die since we may get there before the initialization
* \ingroup simix_synchro_management
*
*/
-smx_cond_t simcall_cond_init(void)
+smx_cond_t simcall_cond_init()
{
return simcall_BODY_cond_init();
}
