-/* Copyright (c) 2007-2009 Da SimGrid Team. All rights reserved. */
+/* Copyright (c) 2006, 2007, 2008, 2009, 2010. The SimGrid Team.
+ * All rights reserved. */
/* This program is free software; you can redistribute it and/or modify it
* under the terms of the license (GNU LGPL) which comes with this package. */
#include "simdag/simdag.h"
#include "xbt/sysdep.h"
#include "xbt/dynar.h"
+#include "instr/private.h"
XBT_LOG_NEW_DEFAULT_SUBCATEGORY(sd_task, sd,
"Logging specific to SimDag (task)");
/* general information */
task->data = data; /* user data */
task->name = xbt_strdup(name);
- task->kind = 0;
+ task->kind = SD_TASK_NOT_TYPED;
task->state_hookup.prev = NULL;
task->state_hookup.next = NULL;
task->state_set = sd_global->not_scheduled_task_set;
/* dependencies */
task->tasks_before = xbt_dynar_new(sizeof(SD_dependency_t), NULL);
task->tasks_after = xbt_dynar_new(sizeof(SD_dependency_t), NULL);
+ task->unsatisfied_dependencies = 0;
+ task->is_not_ready = 0;
/* scheduling parameters */
task->workstation_nb = 0;
task->workstation_list = NULL;
task->computation_amount = NULL;
task->communication_amount = NULL;
- task->rate = 0;
+ task->rate = -1;
sd_global->task_number++;
+#ifdef HAVE_TRACING
+ TRACE_sd_task_create(task);
+#endif
+
return task;
}
*
* \param task a task
* \return the current \ref e_SD_task_state_t "state" of this task:
- * #SD_NOT_SCHEDULED, #SD_SCHEDULED, #SD_READY, #SD_RUNNING, #SD_DONE or #SD_FAILED
+ * #SD_NOT_SCHEDULED, #SD_SCHEDULED, #SD_RUNNABLE, #SD_RUNNING, #SD_DONE or #SD_FAILED
* \see e_SD_task_state_t
*/
e_SD_task_state_t SD_task_get_state(SD_task_t task)
case SD_NOT_SCHEDULED:
task->state_set = sd_global->not_scheduled_task_set;
break;
+ case SD_SCHEDULABLE:
+ task->state_set = sd_global->schedulable_task_set;
+ break;
case SD_SCHEDULED:
task->state_set = sd_global->scheduled_task_set;
break;
- case SD_READY:
- task->state_set = sd_global->ready_task_set;
+ case SD_RUNNABLE:
+ task->state_set = sd_global->runnable_task_set;
break;
case SD_IN_FIFO:
task->state_set = sd_global->in_fifo_task_set;
case SD_RUNNING:
task->state_set = sd_global->running_task_set;
task->start_time =
- surf_workstation_model->action_get_start_time(task->surf_action);
+ surf_workstation_model->action_get_start_time(task->surf_action);
break;
case SD_DONE:
task->state_set = sd_global->done_task_set;
task->finish_time =
- surf_workstation_model->action_get_finish_time(task->surf_action);
+ surf_workstation_model->action_get_finish_time(task->surf_action);
task->remains = 0;
break;
case SD_FAILED:
task->state = new_state;
if (task->watch_points & new_state) {
- INFO1("Watch point reached with task '%s'!", SD_task_get_name(task));
+ VERB1("Watch point reached with task '%s'!", SD_task_get_name(task));
sd_global->watch_point_reached = 1;
SD_task_unwatch(task, new_state); /* remove the watch point */
}
return task->name;
}
+/** @brief Allows to change the name of a task */
+void SD_task_set_name(SD_task_t task, const char *name)
+{
+ xbt_free(task->name);
+ task->name = xbt_strdup(name);
+}
+
/** @brief Returns the dynar of the parents of a task
*
* \param task a task
xbt_assert0(task != NULL, "Invalid parameter");
parents = xbt_dynar_new(sizeof(SD_task_t), NULL);
- xbt_dynar_foreach(task->tasks_before, i, dep){
+ xbt_dynar_foreach(task->tasks_before, i, dep) {
xbt_dynar_push(parents, &(dep->src));
}
return parents;
xbt_assert0(task != NULL, "Invalid parameter");
children = xbt_dynar_new(sizeof(SD_task_t), NULL);
- xbt_dynar_foreach(task->tasks_after, i, dep){
+ xbt_dynar_foreach(task->tasks_after, i, dep) {
xbt_dynar_push(children, &(dep->dst));
}
return children;
SD_CHECK_INIT_DONE();
xbt_assert0(task != NULL, "Invalid parameter");
// xbt_assert1( task->state_set != sd_global->scheduled_task_set,
- // "Unscheduled task %s", task->name);
+ // "Unscheduled task %s", task->name);
return task->workstation_nb;
}
* Only call this on already scheduled tasks!
* \param task a task
*/
-SD_workstation_t* SD_task_get_workstation_list(SD_task_t task)
+SD_workstation_t *SD_task_get_workstation_list(SD_task_t task)
{
SD_CHECK_INIT_DONE();
xbt_assert0(task != NULL, "Invalid parameter");
//xbt_assert1( task->state_set != sd_global->scheduled_task_set,
- // "Unscheduled task %s", task->name);
+ // "Unscheduled task %s", task->name);
return task->workstation_list;
}
return task->remains;
}
-int SD_task_get_kind(SD_task_t task) {
+int SD_task_get_kind(SD_task_t task)
+{
return task->kind;
}
SD_dependency_t dependency;
char *statename;
- INFO1("Displaying task %s",SD_task_get_name(task));
- statename=bprintf("%s %s %s %s %s %s %s",
- (task->state&SD_NOT_SCHEDULED?"not scheduled":""),
- (task->state&SD_SCHEDULED?"scheduled":""),
- (task->state&SD_READY?"ready":"not ready"),
- (task->state&SD_IN_FIFO?"in fifo":""),
- (task->state&SD_RUNNING?"running":""),
- (task->state&SD_DONE?"done":""),
- (task->state&SD_FAILED?"failed":""));
- INFO1(" - state: %s",statename);
+ INFO1("Displaying task %s", SD_task_get_name(task));
+ statename = bprintf("%s %s %s %s %s %s %s %s",
+ (task->state & SD_NOT_SCHEDULED ? "not scheduled" :
+ ""),
+ (task->state & SD_SCHEDULABLE ? "schedulable" : ""),
+ (task->state & SD_SCHEDULED ? "scheduled" : ""),
+ (task->state & SD_RUNNABLE ? "runnable" :
+ "not runnable"),
+ (task->state & SD_IN_FIFO ? "in fifo" : ""),
+ (task->state & SD_RUNNING ? "running" : ""),
+ (task->state & SD_DONE ? "done" : ""),
+ (task->state & SD_FAILED ? "failed" : ""));
+ INFO1(" - state: %s", statename);
free(statename);
- if (task->kind!=0) {
- switch(task->kind){
+ if (task->kind != 0) {
+ switch (task->kind) {
case SD_TASK_COMM_E2E:
INFO0(" - kind: end-to-end communication");
break;
INFO0(" - kind: sequential computation");
break;
default:
- INFO1(" - (unknown kind %d)",task->kind);
+ INFO1(" - (unknown kind %d)", task->kind);
}
}
- INFO1(" - amount: %.0f",SD_task_get_amount(task));
+ INFO1(" - amount: %.0f", SD_task_get_amount(task));
+ INFO1(" - Dependencies to satisfy: %d", task->unsatisfied_dependencies);
if (xbt_dynar_length(task->tasks_before)) {
INFO0(" - pre-dependencies:");
- xbt_dynar_foreach(task->tasks_before,counter,dependency) {
- INFO1(" %s",SD_task_get_name(dependency->src));
+ xbt_dynar_foreach(task->tasks_before, counter, dependency) {
+ INFO1(" %s", SD_task_get_name(dependency->src));
}
}
if (xbt_dynar_length(task->tasks_after)) {
INFO0(" - post-dependencies:");
- xbt_dynar_foreach(task->tasks_after,counter,dependency) {
- INFO1(" %s",SD_task_get_name(dependency->dst));
+ xbt_dynar_foreach(task->tasks_after, counter, dependency) {
+ INFO1(" %s", SD_task_get_name(dependency->dst));
}
}
}
+
/** @brief Dumps the task in dotty formalism into the FILE* passed as second argument */
-void SD_task_dotty(SD_task_t task,void* out) {
+void SD_task_dotty(SD_task_t task, void *out)
+{
unsigned int counter;
SD_dependency_t dependency;
- fprintf(out, " T%p [label=\"%.20s\"",task, task->name);
- switch(task->kind){
- case SD_TASK_COMM_E2E:
- fprintf(out,", shape=box");
- break;
- case SD_TASK_COMP_SEQ:
- fprintf(out,", shape=circle");
- break;
- default:
- xbt_die("Unknown task type!");
+ fprintf(out, " T%p [label=\"%.20s\"", task, task->name);
+ switch (task->kind) {
+ case SD_TASK_COMM_E2E:
+ fprintf(out, ", shape=box");
+ break;
+ case SD_TASK_COMP_SEQ:
+ fprintf(out, ", shape=circle");
+ break;
+ default:
+ xbt_die("Unknown task type!");
}
- fprintf(out,"];\n");
- xbt_dynar_foreach(task->tasks_before,counter,dependency) {
- fprintf(out," T%p -> T%p;\n",dependency->src, dependency->dst);
+ fprintf(out, "];\n");
+ xbt_dynar_foreach(task->tasks_before, counter, dependency) {
+ fprintf(out, " T%p -> T%p;\n", dependency->src, dependency->dst);
}
}
* \brief Adds a dependency between two tasks
*
* \a dst will depend on \a src, ie \a dst will not start before \a src is finished.
- * Their \ref e_SD_task_state_t "state" must be #SD_NOT_SCHEDULED, #SD_SCHEDULED or #SD_READY.
+ * Their \ref e_SD_task_state_t "state" must be #SD_NOT_SCHEDULED, #SD_SCHEDULED or #SD_RUNNABLE.
*
* \param name the name of the new dependency (can be \c NULL)
* \param data the user data you want to associate with this dependency (can be \c NULL)
"Cannot add a dependency between task '%s' and itself",
SD_task_get_name(src));
- if (!__SD_task_is_not_scheduled(src)
- && !__SD_task_is_scheduled_or_ready(src))
+ if (!__SD_task_is_not_scheduled(src) && !__SD_task_is_schedulable(src)
+ && !__SD_task_is_scheduled_or_runnable(src))
THROW1(arg_error, 0,
- "Task '%s' must be SD_NOT_SCHEDULED, SD_SCHEDULED or SD_READY",
+ "Task '%s' must be SD_NOT_SCHEDULED, SD_SCHEDULABLE, SD_SCHEDULED or SD_RUNNABLE",
SD_task_get_name(src));
- if (!__SD_task_is_not_scheduled(dst)
- && !__SD_task_is_scheduled_or_ready(dst))
+ if (!__SD_task_is_not_scheduled(dst) && !__SD_task_is_schedulable(dst)
+ && !__SD_task_is_scheduled_or_runnable(dst))
THROW1(arg_error, 0,
- "Task '%s' must be SD_NOT_SCHEDULED, SD_SCHEDULED or SD_READY",
+ "Task '%s' must be SD_NOT_SCHEDULED, SD_SCHEDULABLE, SD_SCHEDULED or SD_RUNNABLE",
SD_task_get_name(dst));
- DEBUG2("SD_task_dependency_add: src = %s, dst = %s", SD_task_get_name(src),
- SD_task_get_name(dst));
+ DEBUG2("SD_task_dependency_add: src = %s, dst = %s",
+ SD_task_get_name(src), SD_task_get_name(dst));
for (i = 0; i < length && !found; i++) {
xbt_dynar_get_cpy(dynar, i, &dependency);
found = (dependency->dst == dst);
dependency = xbt_new(s_SD_dependency_t, 1);
- dependency->name = xbt_strdup(name); /* xbt_strdup is cleaver enough to deal with NULL args itself */
+ dependency->name = xbt_strdup(name); /* xbt_strdup is cleaver enough to deal with NULL args itself */
dependency->data = data;
dependency->src = src;
dependency->dst = dst;
xbt_dynar_push(src->tasks_after, &dependency);
xbt_dynar_push(dst->tasks_before, &dependency);
- /* if the task was ready, then dst->tasks_before is not empty anymore,
+ dst->unsatisfied_dependencies++;
+ dst->is_not_ready++;
+
+ /* if the task was runnable, then dst->tasks_before is not empty anymore,
so we must go back to state SD_SCHEDULED */
- if (__SD_task_is_ready(dst)) {
- DEBUG1("SD_task_dependency_add: %s was ready and becomes scheduled!",
- SD_task_get_name(dst));
+ if (__SD_task_is_runnable(dst)) {
+ DEBUG1
+ ("SD_task_dependency_add: %s was runnable and becomes scheduled!",
+ SD_task_get_name(dst));
__SD_task_set_state(dst, SD_SCHEDULED);
}
SD_dependency_t dependency;
SD_CHECK_INIT_DONE();
- xbt_assert0(src != NULL || dst != NULL, "Invalid parameter: both src and dst are NULL");
+ xbt_assert0(src != NULL
+ || dst != NULL,
+ "Invalid parameter: both src and dst are NULL");
if (src) {
if (dst) {
- xbt_dynar_foreach(src->tasks_after,counter,dependency) {
+ xbt_dynar_foreach(src->tasks_after, counter, dependency) {
if (dependency->dst == dst)
return 1;
}
if (dependency->src == src) {
xbt_dynar_remove_at(dynar, i, NULL);
__SD_task_dependency_destroy(dependency);
+ dst->unsatisfied_dependencies--;
+ dst->is_not_ready--;
found = 1;
}
}
SD_task_get_name(dst), SD_task_get_name(src),
SD_task_get_name(src), SD_task_get_name(dst));
- /* if the task was scheduled and dst->tasks_before is empty now, we can make it ready */
- if (xbt_dynar_length(dst->tasks_before) == 0 && __SD_task_is_scheduled(dst))
- __SD_task_set_state(dst, SD_READY);
+ /* if the task was scheduled and dst->tasks_before is empty now, we can make it runnable */
+
+ if (dst->unsatisfied_dependencies == 0) {
+ if (__SD_task_is_scheduled(dst))
+ __SD_task_set_state(dst, SD_RUNNABLE);
+ else
+ __SD_task_set_state(dst, SD_SCHEDULABLE);
+ }
+
+ if (dst->is_not_ready == 0)
+ __SD_task_set_state(dst, SD_SCHEDULABLE);
/* __SD_print_dependencies(src);
__SD_print_dependencies(dst); */
static void __SD_print_watch_points(SD_task_t task)
{
static const int state_masks[] =
- { SD_SCHEDULED, SD_RUNNING, SD_READY, SD_DONE, SD_FAILED };
+ { SD_SCHEDULABLE, SD_SCHEDULED, SD_RUNNING, SD_RUNNABLE, SD_DONE,
+ SD_FAILED
+ };
static const char *state_names[] =
- { "scheduled", "running", "ready", "done", "failed" };
+ { "schedulable", "scheduled", "running", "runnable", "done",
+ "failed"
+ };
int i;
INFO2("Task '%s' watch points (%x): ", SD_task_get_name(task),
* \param workstation_list the workstations on which the task would be executed
* \param computation_amount computation amount for each workstation
* \param communication_amount communication amount between each pair of workstations
- * \param rate task execution speed rate
* \see SD_schedule()
*/
double SD_task_get_execution_time(SD_task_t task,
int workstation_nb,
- const SD_workstation_t * workstation_list,
+ const SD_workstation_t *
+ workstation_list,
const double *computation_amount,
- const double *communication_amount,
- double rate)
+ const double *communication_amount)
{
double time, max_time = 0.0;
int i, j;
SD_CHECK_INIT_DONE();
- xbt_assert0(task != NULL && workstation_nb > 0 && workstation_list != NULL
- && computation_amount != NULL
- && communication_amount != NULL, "Invalid parameter");
+ xbt_assert0(task != NULL && workstation_nb > 0
+ && workstation_list != NULL, "Invalid parameter");
/* the task execution time is the maximum execution time of the parallel tasks */
for (i = 0; i < workstation_nb; i++) {
- time =
- SD_workstation_get_computation_time(workstation_list[i],
- computation_amount[i]);
-
- for (j = 0; j < workstation_nb; j++) {
- time +=
- SD_route_get_communication_time(workstation_list[i],
- workstation_list[j],
- communication_amount[i *
- workstation_nb +
- j]);
- }
+ time = 0.0;
+ if (computation_amount != NULL)
+ time =
+ SD_workstation_get_computation_time(workstation_list[i],
+ computation_amount[i]);
+
+ if (communication_amount != NULL)
+ for (j = 0; j < workstation_nb; j++) {
+ time +=
+ SD_route_get_communication_time(workstation_list[i],
+ workstation_list[j],
+ communication_amount[i *
+ workstation_nb
+ + j]);
+ }
if (time > max_time) {
max_time = time;
}
return max_time;
}
-static inline void SD_task_do_schedule(SD_task_t task) {
+
+static XBT_INLINE void SD_task_do_schedule(SD_task_t task)
+{
SD_CHECK_INIT_DONE();
- if (!__SD_task_is_not_scheduled(task))
- THROW1(arg_error, 0, "Task '%s' has already been scheduled",
- SD_task_get_name(task));
+ if (!__SD_task_is_not_scheduled(task) && !__SD_task_is_schedulable(task))
+ THROW1(arg_error, 0, "Task '%s' has already been scheduled",
+ SD_task_get_name(task));
- /* update the task state */
- if (xbt_dynar_length(task->tasks_before) == 0)
- __SD_task_set_state(task, SD_READY);
+ /* update the task state */
+ if (task->unsatisfied_dependencies == 0)
+ __SD_task_set_state(task, SD_RUNNABLE);
else
__SD_task_set_state(task, SD_SCHEDULED);
}
const double *computation_amount,
const double *communication_amount, double rate)
{
- xbt_assert0(workstation_count > 0, "workstation_nb must be positive");
-
int communication_nb;
+ task->workstation_nb = 0;
+ task->rate = -1;
+ xbt_assert0(workstation_count > 0, "workstation_nb must be positive");
task->workstation_nb = workstation_count;
task->rate = rate;
- task->computation_amount = xbt_new(double, workstation_count);
- memcpy(task->computation_amount, computation_amount,
- sizeof(double) * workstation_count);
+ if (computation_amount) {
+ task->computation_amount = xbt_new(double, workstation_count);
+ memcpy(task->computation_amount, computation_amount,
+ sizeof(double) * workstation_count);
+ } else {
+ task->computation_amount = NULL;
+ }
communication_nb = workstation_count * workstation_count;
- task->communication_amount = xbt_new(double, communication_nb);
- memcpy(task->communication_amount, communication_amount,
- sizeof(double) * communication_nb);
+ if (communication_amount) {
+ task->communication_amount = xbt_new(double, communication_nb);
+ memcpy(task->communication_amount, communication_amount,
+ sizeof(double) * communication_nb);
+ } else {
+ task->communication_amount = NULL;
+ }
task->workstation_list = xbt_new(SD_workstation_t, workstation_count);
memcpy(task->workstation_list, workstation_list,
SD_task_do_schedule(task);
}
+
/**
* \brief Unschedules a task
*
- * The task state must be #SD_SCHEDULED, #SD_READY, #SD_RUNNING or #SD_FAILED.
+ * The task state must be #SD_SCHEDULED, #SD_RUNNABLE, #SD_RUNNING or #SD_FAILED.
* If you call this function, the task state becomes #SD_NOT_SCHEDULED.
* Call SD_task_schedule() to schedule it again.
*
xbt_assert0(task != NULL, "Invalid parameter");
if (task->state_set != sd_global->scheduled_task_set &&
- task->state_set != sd_global->ready_task_set &&
+ task->state_set != sd_global->runnable_task_set &&
task->state_set != sd_global->running_task_set &&
task->state_set != sd_global->failed_task_set)
THROW1(arg_error, 0,
- "Task %s: the state must be SD_SCHEDULED, SD_READY, SD_RUNNING or SD_FAILED",
+ "Task %s: the state must be SD_SCHEDULED, SD_RUNNABLE, SD_RUNNING or SD_FAILED",
SD_task_get_name(task));
- if (__SD_task_is_scheduled_or_ready(task)) /* if the task is scheduled or ready */
+ if (__SD_task_is_scheduled_or_runnable(task) /* if the task is scheduled or runnable */
+ &&task->kind == SD_TASK_NOT_TYPED) /* Don't free scheduling data for typed tasks */
__SD_task_destroy_scheduling_data(task);
if (__SD_task_is_running(task)) /* the task should become SD_FAILED */
surf_workstation_model->action_cancel(task->surf_action);
- else
- __SD_task_set_state(task, SD_NOT_SCHEDULED);
+ else {
+ if (task->unsatisfied_dependencies == 0)
+ __SD_task_set_state(task, SD_SCHEDULABLE);
+ else
+ __SD_task_set_state(task, SD_NOT_SCHEDULED);
+ }
task->remains = task->amount;
task->start_time = -1.0;
}
-/* Destroys the data memorised by SD_task_schedule. Task state must be SD_SCHEDULED or SD_READY.
+/* Destroys the data memorized by SD_task_schedule. Task state must be SD_SCHEDULED or SD_RUNNABLE.
*/
static void __SD_task_destroy_scheduling_data(SD_task_t task)
{
SD_CHECK_INIT_DONE();
- if (!__SD_task_is_scheduled_or_ready(task) && !__SD_task_is_in_fifo(task))
+ if (!__SD_task_is_scheduled_or_runnable(task)
+ && !__SD_task_is_in_fifo(task))
THROW1(arg_error, 0,
- "Task '%s' must be SD_SCHEDULED, SD_READY or SD_IN_FIFO",
+ "Task '%s' must be SD_SCHEDULED, SD_RUNNABLE or SD_IN_FIFO",
SD_task_get_name(task));
xbt_free(task->computation_amount);
SD_CHECK_INIT_DONE();
xbt_assert0(task != NULL, "Invalid parameter");
- xbt_assert2(__SD_task_is_ready_or_in_fifo(task),
- "Task '%s' is not ready or in a fifo! Task state: %d",
+ xbt_assert2(__SD_task_is_runnable_or_in_fifo(task),
+ "Task '%s' is not runnable or in a fifo! Task state: %d",
SD_task_get_name(task), SD_task_get_state(task));
xbt_assert1(task->workstation_list != NULL,
- "Task '%s': workstation_list is NULL!", SD_task_get_name(task));
+ "Task '%s': workstation_list is NULL!",
+ SD_task_get_name(task));
/* we have to create a Surf workstation array instead of the SimDag workstation array */
surf_workstations = xbt_new(void *, task->workstation_nb);
- for (i = 0; i < task->workstation_nb; i++) {
+ for (i = 0; i < task->workstation_nb; i++)
surf_workstations[i] = task->workstation_list[i]->surf_workstation;
- }
+
+ /* It's allowed to pass a NULL vector as cost to mean vector of 0.0 (easing user's life). Let's deal with it */
+#define cost_or_zero(array,pos) ((array)?(array)[pos]:0.0)
task->surf_action = NULL;
- if ((task->workstation_nb == 1) && (task->communication_amount[0] == 0.0)) {
+ if ((task->workstation_nb == 1)
+ && (cost_or_zero(task->communication_amount, 0) == 0.0)) {
task->surf_action =
- surf_workstation_model->extension.
- workstation.execute(surf_workstations[0], task->computation_amount[0]);
+ surf_workstation_model->extension.
+ workstation.execute(surf_workstations[0],
+ cost_or_zero(task->computation_amount, 0));
} else if ((task->workstation_nb == 1)
- && (task->computation_amount[0] == 0.0)) {
+ && (cost_or_zero(task->computation_amount, 0) == 0.0)) {
+
task->surf_action =
- surf_workstation_model->extension.
- workstation.communicate(surf_workstations[0], surf_workstations[0],
- task->communication_amount[0], task->rate);
+ surf_workstation_model->extension.
+ workstation.communicate(surf_workstations[0], surf_workstations[0],
+ cost_or_zero(task->communication_amount,
+ 0), task->rate);
} else if ((task->workstation_nb == 2)
- && (task->computation_amount[0] == 0.0)
- && (task->computation_amount[1] == 0.0)) {
+ && (cost_or_zero(task->computation_amount, 0) == 0.0)
+ && (cost_or_zero(task->computation_amount, 1) == 0.0)) {
int nb = 0;
double value = 0.0;
for (i = 0; i < task->workstation_nb * task->workstation_nb; i++) {
- if (task->communication_amount[i] > 0.0) {
+ if (cost_or_zero(task->communication_amount, i) > 0.0) {
nb++;
- value = task->communication_amount[i];
+ value = cost_or_zero(task->communication_amount, i);
}
}
if (nb == 1) {
task->surf_action =
- surf_workstation_model->extension.
- workstation.communicate(surf_workstations[0], surf_workstations[1],
- value, task->rate);
+ surf_workstation_model->extension.
+ workstation.communicate(surf_workstations[0],
+ surf_workstations[1], value, task->rate);
}
}
+#undef cost_or_zero
+
if (!task->surf_action) {
double *computation_amount = xbt_new(double, task->workstation_nb);
double *communication_amount = xbt_new(double, task->workstation_nb *
sizeof(double) * task->workstation_nb * task->workstation_nb);
task->surf_action =
- surf_workstation_model->extension.
- workstation.execute_parallel_task(task->workstation_nb,
- surf_workstations, computation_amount,
- communication_amount, task->amount,
- task->rate);
+ surf_workstation_model->extension.
+ workstation.execute_parallel_task(task->workstation_nb,
+ surf_workstations,
+ computation_amount,
+ communication_amount,
+ task->amount, task->rate);
} else {
xbt_free(surf_workstations);
}
DEBUG1("surf_action = %p", task->surf_action);
+#ifdef HAVE_TRACING
+ if (task->category)
+ TRACE_surf_action(task->surf_action, task->category);
+#endif
+
__SD_task_destroy_scheduling_data(task); /* now the scheduling data are not useful anymore */
__SD_task_set_state(task, SD_RUNNING);
xbt_assert2(__SD_task_is_running(task), "Bad state of task '%s': %d",
}
-/* Tries to run a task. This function is called by SD_simulate() when a scheduled task becomes SD_READY
+/* Tries to run a task. This function is called by SD_simulate() when a scheduled task becomes SD_RUNNABLE
* (ie when its dependencies are satisfied).
* If one of the workstations where the task is scheduled on is busy (in sequential mode),
* the task doesn't start.
SD_CHECK_INIT_DONE();
xbt_assert0(task != NULL, "Invalid parameter");
- xbt_assert2(__SD_task_is_ready(task),
- "Task '%s' is not ready! Task state: %d",
+ xbt_assert2(__SD_task_is_runnable(task),
+ "Task '%s' is not runnable! Task state: %d",
SD_task_get_name(task), SD_task_get_state(task));
for (i = 0; i < task->workstation_nb; i++) {
- can_start = !__SD_workstation_is_busy(task->workstation_list[i]);
+ can_start = can_start &&
+ !__SD_workstation_is_busy(task->workstation_list[i]);
}
DEBUG2("Task '%s' can start: %d", SD_task_get_name(task), can_start);
workstation = task->workstation_list[i];
if (workstation->access_mode == SD_WORKSTATION_SEQUENTIAL_ACCESS) {
DEBUG2("Pushing task '%s' in the fifo of workstation '%s'",
- SD_task_get_name(task), SD_workstation_get_name(workstation));
+ SD_task_get_name(task),
+ SD_workstation_get_name(workstation));
xbt_fifo_push(workstation->task_fifo, task);
}
}
"The task must be running! Task state: %d",
SD_task_get_state(task));
xbt_assert1(task->workstation_list != NULL,
- "Task '%s': workstation_list is NULL!", SD_task_get_name(task));
+ "Task '%s': workstation_list is NULL!",
+ SD_task_get_name(task));
candidates = xbt_new(SD_task_t, 8);
DEBUG0("Getting candidate in fifo");
candidate =
- xbt_fifo_get_item_content(xbt_fifo_get_first_item
- (workstation->task_fifo));
+ xbt_fifo_get_item_content(xbt_fifo_get_first_item
+ (workstation->task_fifo));
if (candidate != NULL) {
DEBUG1("Candidate: '%s'", SD_task_get_name(candidate));
if (candidate_nb == candidate_capacity) {
candidate_capacity *= 2;
candidates =
- xbt_realloc(candidates, sizeof(SD_task_t) * candidate_capacity);
+ xbt_realloc(candidates,
+ sizeof(SD_task_t) * candidate_capacity);
}
/* register the candidate */
/* I can start on this workstation if the workstation is shared
or if I am the first task in the fifo */
- can_start = workstation->access_mode == SD_WORKSTATION_SHARED_ACCESS ||
- candidate ==
- xbt_fifo_get_item_content(xbt_fifo_get_first_item
- (workstation->task_fifo));
+ can_start = workstation->access_mode == SD_WORKSTATION_SHARED_ACCESS
+ || candidate ==
+ xbt_fifo_get_item_content(xbt_fifo_get_first_item
+ (workstation->task_fifo));
}
DEBUG2("Candidate '%s' can start: %d", SD_task_get_name(candidate),
if (workstation->access_mode == SD_WORKSTATION_SEQUENTIAL_ACCESS) {
candidate = xbt_fifo_shift(workstation->task_fifo); /* the return value is stored just for debugging */
DEBUG1("Head of the fifo: '%s'",
- (candidate != NULL) ? SD_task_get_name(candidate) : "NULL");
+ (candidate !=
+ NULL) ? SD_task_get_name(candidate) : "NULL");
xbt_assert0(candidate == candidates[i],
"Error in __SD_task_just_done: bad first task in the fifo");
}
__SD_task_really_run(candidate);
DEBUG4
- ("Calling __SD_task_is_running: task '%s', state set: %p, running_task_set: %p, is running: %d",
- SD_task_get_name(candidate), candidate->state_set,
- sd_global->running_task_set, __SD_task_is_running(candidate));
+ ("Calling __SD_task_is_running: task '%s', state set: %p, running_task_set: %p, is running: %d",
+ SD_task_get_name(candidate), candidate->state_set,
+ sd_global->running_task_set, __SD_task_is_running(candidate));
xbt_assert2(__SD_task_is_running(candidate),
- "Bad state of task '%s': %d", SD_task_get_name(candidate),
+ "Bad state of task '%s': %d",
+ SD_task_get_name(candidate),
SD_task_get_state(candidate));
DEBUG0("Okay, the task is running.");
SD_CHECK_INIT_DONE();
xbt_assert0(task != NULL, "Invalid parameter");
if (task->surf_action)
- return surf_workstation_model->action_get_start_time(task->surf_action);
+ return surf_workstation_model->
+ action_get_start_time(task->surf_action);
else
return task->start_time;
}
xbt_assert0(task != NULL, "Invalid parameter");
if (task->surf_action) /* should never happen as actions are destroyed right after their completion */
- return surf_workstation_model->action_get_finish_time(task->surf_action);
+ return surf_workstation_model->
+ action_get_finish_time(task->surf_action);
else
return task->finish_time;
}
DEBUG1("Destroying task %s...", SD_task_get_name(task));
__SD_task_remove_dependencies(task);
- /* if the task was scheduled or ready we have to free the scheduling parameters */
- if (__SD_task_is_scheduled_or_ready(task))
+ /* if the task was scheduled or runnable we have to free the scheduling parameters */
+ if (__SD_task_is_scheduled_or_runnable(task))
__SD_task_destroy_scheduling_data(task);
- xbt_swag_remove(task,task->state_set);
+ xbt_swag_remove(task, task->state_set);
if (task->name != NULL)
xbt_free(task->name);
if (task->computation_amount)
xbt_free(task->computation_amount);
+#ifdef HAVE_TRACING
+ TRACE_sd_task_destroy(task);
+#endif
+
xbt_dynar_free(&task->tasks_before);
xbt_dynar_free(&task->tasks_after);
xbt_free(task);
}
-static inline SD_task_t SD_task_create_sized(const char*name,void*data,double amount,int ws_count) {
- SD_task_t task = SD_task_create(name,data,amount);
- task->communication_amount = xbt_new0(double,ws_count*ws_count);
- task->computation_amount = xbt_new0(double,ws_count);
+static XBT_INLINE SD_task_t SD_task_create_sized(const char *name,
+ void *data, double amount,
+ int ws_count)
+{
+ SD_task_t task = SD_task_create(name, data, amount);
+ task->communication_amount = xbt_new0(double, ws_count * ws_count);
+ task->computation_amount = xbt_new0(double, ws_count);
task->workstation_nb = ws_count;
- task->workstation_list = xbt_new0(SD_workstation_t,ws_count);
+ task->workstation_list = xbt_new0(SD_workstation_t, ws_count);
return task;
}
+
/** @brief create a end-to-end communication task that can then be auto-scheduled
*
* Auto-scheduling mean that the task can be used with SD_task_schedulev(). This
* A end-to-end communication must be scheduled on 2 hosts, and the amount
* specified at creation is sent from hosts[0] to hosts[1].
*/
-SD_task_t SD_task_create_comm_e2e(const char*name, void *data, double amount) {
- SD_task_t res = SD_task_create_sized(name,data,amount,2);
+SD_task_t SD_task_create_comm_e2e(const char *name, void *data,
+ double amount)
+{
+ SD_task_t res = SD_task_create_sized(name, data, amount, 2);
res->communication_amount[2] = amount;
- res->kind=SD_TASK_COMM_E2E;
+ res->kind = SD_TASK_COMM_E2E;
return res;
}
+
/** @brief create a sequential computation task that can then be auto-scheduled
*
* Auto-scheduling mean that the task can be used with SD_task_schedulev(). This
* A sequential computation must be scheduled on 1 host, and the amount
* specified at creation to be run on hosts[0].
*/
-SD_task_t SD_task_create_comp_seq(const char*name, void *data, double amount) {
- SD_task_t res = SD_task_create_sized(name,data,amount,1);
- res->computation_amount[0]=amount;
- res->kind=SD_TASK_COMP_SEQ;
+SD_task_t SD_task_create_comp_seq(const char *name, void *data,
+ double amount)
+{
+ SD_task_t res = SD_task_create_sized(name, data, amount, 1);
+ res->computation_amount[0] = amount;
+ res->kind = SD_TASK_COMP_SEQ;
return res;
}
* - parallel tasks with no internal communication (one kind per speedup model such as amdal)
* - idem+ internal communication. Task type not enough since we cannot store comm cost alongside to comp one)
*/
-void SD_task_schedulev(SD_task_t task, int count, const SD_workstation_t*list) {
+void SD_task_schedulev(SD_task_t task, int count,
+ const SD_workstation_t * list)
+{
int i;
- xbt_assert1(task->kind != 0,"Task %s is not typed. Cannot automatically schedule it.",SD_task_get_name(task));
- switch(task->kind) {
+ SD_dependency_t dep;
+ unsigned int cpt;
+ xbt_assert1(task->kind != 0,
+ "Task %s is not typed. Cannot automatically schedule it.",
+ SD_task_get_name(task));
+ switch (task->kind) {
case SD_TASK_COMM_E2E:
case SD_TASK_COMP_SEQ:
- xbt_assert(task->workstation_nb==count);
- for (i=0;i<count;i++)
- task->workstation_list[i]=list[i];
+ xbt_assert(task->workstation_nb == count);
+ for (i = 0; i < count; i++)
+ task->workstation_list[i] = list[i];
SD_task_do_schedule(task);
break;
default:
xbt_die(bprintf("Kind of task %s not supported by SD_task_schedulev()",
- SD_task_get_name(task)));
+ SD_task_get_name(task)));
}
if (task->kind == SD_TASK_COMM_E2E) {
VERB4("Schedule comm task %s between %s -> %s. It costs %.f bytes",
- SD_task_get_name(task),
- SD_workstation_get_name(task->workstation_list[0]),SD_workstation_get_name(task->workstation_list[1]),
- task->communication_amount[2]);
+ SD_task_get_name(task),
+ SD_workstation_get_name(task->workstation_list[0]),
+ SD_workstation_get_name(task->workstation_list[1]),
+ task->communication_amount[2]);
}
- /* Iterate over all childs and parent being COMM_E2E to say where I am located (and start them if ready) */
+ /* Iterate over all childs and parent being COMM_E2E to say where I am located (and start them if runnable) */
if (task->kind == SD_TASK_COMP_SEQ) {
VERB3("Schedule computation task %s on %s. It costs %.f flops",
- SD_task_get_name(task),SD_workstation_get_name(task->workstation_list[0]),
- task->computation_amount[0]);
- SD_dependency_t dep;
- unsigned int cpt;
- xbt_dynar_foreach(task->tasks_before,cpt,dep) {
+ SD_task_get_name(task),
+ SD_workstation_get_name(task->workstation_list[0]),
+ task->computation_amount[0]);
+
+ xbt_dynar_foreach(task->tasks_before, cpt, dep) {
SD_task_t before = dep->src;
if (before->kind == SD_TASK_COMM_E2E) {
before->workstation_list[1] = task->workstation_list[0];
- if (before->workstation_list[0] && __SD_task_is_not_scheduled(before)) {
+
+ if (before->workstation_list[0] &&
+ (__SD_task_is_schedulable(before)
+ || __SD_task_is_not_scheduled(before))) {
SD_task_do_schedule(before);
- VERB4("Auto-Schedule comm task %s between %s -> %s. It costs %.f bytes",
- SD_task_get_name(before),
- SD_workstation_get_name(before->workstation_list[0]),SD_workstation_get_name(before->workstation_list[1]),
- before->communication_amount[2]);
+ VERB4
+ ("Auto-Schedule comm task %s between %s -> %s. It costs %.f bytes",
+ SD_task_get_name(before),
+ SD_workstation_get_name(before->workstation_list[0]),
+ SD_workstation_get_name(before->workstation_list[1]),
+ before->communication_amount[2]);
}
}
}
- xbt_dynar_foreach(task->tasks_after,cpt,dep) {
+ xbt_dynar_foreach(task->tasks_after, cpt, dep) {
SD_task_t after = dep->dst;
if (after->kind == SD_TASK_COMM_E2E) {
after->workstation_list[0] = task->workstation_list[0];
- if (after->workstation_list[1] && __SD_task_is_not_scheduled(after)) {
+ //J-N : Why did you comment on these line (this comment add a bug I think)?
+ if (after->workstation_list[1]
+ && (__SD_task_is_not_scheduled(after)
+ || __SD_task_is_schedulable(after))) {
SD_task_do_schedule(after);
- VERB4("Auto-Schedule comm task %s between %s -> %s. It costs %.f bytes",
- SD_task_get_name(after),
- SD_workstation_get_name(after->workstation_list[0]),SD_workstation_get_name(after->workstation_list[1]),
- after->communication_amount[2]);
+ VERB4
+ ("Auto-Schedule comm task %s between %s -> %s. It costs %.f bytes",
+ SD_task_get_name(after),
+ SD_workstation_get_name(after->workstation_list[0]),
+ SD_workstation_get_name(after->workstation_list[1]),
+ after->communication_amount[2]);
}
}
}
}
}
+
/** @brief autoschedule a task on a list of workstations
*
* This function is very similar to SD_task_schedulev(),
* but takes the list of workstations to schedule onto as separate parameters.
* It builds a proper vector of workstations and then call SD_task_schedulev()
*/
-void SD_task_schedulel(SD_task_t task, int count, ...) {
+void SD_task_schedulel(SD_task_t task, int count, ...)
+{
va_list ap;
- SD_workstation_t *list=xbt_new(SD_workstation_t,count);
+ SD_workstation_t *list = xbt_new(SD_workstation_t, count);
int i;
- va_start(ap,count);
- for (i=0;i<count;i++) {
- list[i] = va_arg(ap,SD_workstation_t);
+ va_start(ap, count);
+ for (i = 0; i < count; i++) {
+ list[i] = va_arg(ap, SD_workstation_t);
}
va_end(ap);
- SD_task_schedulev(task,count,list);
+ SD_task_schedulev(task, count, list);
free(list);
}