-/* Copyright (c) 2009-2017. The SimGrid Team.
+/* Copyright (c) 2009-2021. 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_private.hpp"
+#include "simgrid/s4u/Engine.hpp"
#include "simgrid/simdag.h"
#include "src/internal_config.h"
-#include "xbt/file.h"
-#include <string.h>
+#include "xbt/file.hpp"
+#include <algorithm>
+#include <cstring>
#include <unordered_map>
-
-XBT_LOG_NEW_DEFAULT_SUBCATEGORY(sd_dotparse, sd, "Parsing DOT files");
+#include <vector>
#if HAVE_GRAPHVIZ
#include <graphviz/cgraph.h>
+XBT_LOG_NEW_DEFAULT_SUBCATEGORY(sd_dotparse, sd, "Parsing DOT files");
+
xbt_dynar_t SD_dotload_generic(const char* filename, bool sequential, bool schedule);
static void dot_task_p_free(void *task) {
- SD_task_destroy(*(SD_task_t *)task);
+ (*(SD_task_t*)task)->destroy();
}
/** @brief loads a DOT file describing a DAG
* The size attribute of a node describes:
* - for a compute task: the amount of flops to execute
* - for a communication task : the amount of bytes to transfer
- * If this attribute is ommited, the default value is zero.
+ * If this attribute is omitted, the default value is zero.
*/
xbt_dynar_t SD_dotload(const char *filename) {
return SD_dotload_generic(filename, true, false);
return SD_dotload_generic(filename, true, true);
}
-static int edge_compare(const void *a, const void *b)
-{
- unsigned va = AGSEQ(*(Agedge_t **)a);
- unsigned vb = AGSEQ(*(Agedge_t **)b);
- if (va == vb)
- return 0;
- else
- return (va < vb ? -1 : 1);
-}
-
xbt_dynar_t SD_dotload_generic(const char* filename, bool sequential, bool schedule)
{
xbt_assert(filename, "Unable to use a null file descriptor\n");
FILE *in_file = fopen(filename, "r");
xbt_assert(in_file != nullptr, "Failed to open file: %s", filename);
- unsigned int i;
SD_task_t root;
SD_task_t end;
SD_task_t task;
- xbt_dynar_t computer = nullptr;
- xbt_dict_cursor_t dict_cursor;
+ std::vector<SD_task_t>* computer;
+ std::unordered_map<std::string, std::vector<SD_task_t>*> computers;
bool schedule_success = true;
std::unordered_map<std::string, SD_task_t> jobs;
Agraph_t * dag_dot = agread(in_file, NIL(Agdisc_t *));
- xbt_dict_t computers = xbt_dict_new_homogeneous(nullptr);
-
/* Create all the nodes */
Agnode_t *node = nullptr;
for (node = agfstnode(dag_dot); node; node = agnxtnode(dag_dot, node)) {
if (jobs.find(name) == jobs.end()) {
if (sequential) {
XBT_DEBUG("See <job id=%s amount =%.0f>", name, amount);
- task = SD_task_create_comp_seq(name, nullptr , amount);
+ task = simgrid::sd::Task::create_comp_seq(name, amount, nullptr);
} else {
double alpha = atof(agget(node, (char *) "alpha"));
XBT_DEBUG("See <job id=%s amount =%.0f alpha = %.3f>", name, amount, alpha);
- task = SD_task_create_comp_par_amdahl(name, nullptr , amount, alpha);
+ task = simgrid::sd::Task::create_comp_par_amdahl(name, amount, nullptr, alpha);
}
jobs.insert({std::string(name), task});
if (strcmp(name,"root") && strcmp(name,"end"))
xbt_dynar_push(result, &task);
- if ((sequential) &&
- ((schedule && schedule_success) || XBT_LOG_ISENABLED(sd_dotparse, xbt_log_priority_verbose))) {
+ if (sequential && ((schedule && schedule_success) || XBT_LOG_ISENABLED(sd_dotparse, xbt_log_priority_verbose))) {
/* try to take the information to schedule the task only if all is right*/
char *char_performer = agget(node, (char *) "performer");
char *char_order = agget(node, (char *) "order");
if ((performer != -1 && order != -1) && performer < static_cast<int>(sg_host_count())) {
/* required parameters are given and less performers than hosts are required */
- XBT_DEBUG ("Task '%s' is scheduled on workstation '%d' in position '%d'", task->name, performer, order);
- computer = static_cast<xbt_dynar_t> (xbt_dict_get_or_null(computers, char_performer));
- if(computer == nullptr){
- computer = xbt_dynar_new(sizeof(SD_task_t), nullptr);
- xbt_dict_set(computers, char_performer, computer, nullptr);
+ XBT_DEBUG("Task '%s' is scheduled on workstation '%d' in position '%d'", task->get_cname(), performer, order);
+ auto comp = computers.find(char_performer);
+ if (comp != computers.end()) {
+ computer = comp->second;
+ } else {
+ computer = new std::vector<SD_task_t>();
+ computers.insert({char_performer, computer});
}
-
- if(static_cast<unsigned int>(order) < xbt_dynar_length(computer)){
- SD_task_t *task_test = (SD_task_t *)xbt_dynar_get_ptr(computer,order);
- if(*task_test && *task_test != task){
+ if (static_cast<unsigned int>(order) < computer->size()) {
+ const_SD_task_t task_test = computer->at(order);
+ if (task_test && task_test != task) {
/* the user gave the same order to several tasks */
schedule_success = false;
XBT_VERB("Task '%s' wants to start on performer '%s' at the same position '%s' as task '%s'",
- (*task_test)->name, char_performer, char_order, task->name);
+ task_test->get_cname(), char_performer, char_order, task->get_cname());
continue;
}
- }
- /* the parameter seems to be ok */
- xbt_dynar_set_as(computer, order, SD_task_t, task);
+ } else
+ computer->resize(order);
+
+ computer->insert(computer->begin() + order, task);
} else {
/* one of required parameters is not given */
schedule_success = false;
- XBT_VERB("The schedule is ignored, task '%s' can not be scheduled on %d hosts", task->name, performer);
+ XBT_VERB("The schedule is ignored, task '%s' can not be scheduled on %d hosts", task->get_cname(), performer);
}
}
} else {
/*Check if 'root' and 'end' nodes have been explicitly declared. If not, create them. */
if (jobs.find("root") == jobs.end())
- root = (sequential ? SD_task_create_comp_seq("root", nullptr, 0)
- : SD_task_create_comp_par_amdahl("root", nullptr, 0, 0));
+ root = (sequential ? simgrid::sd::Task::create_comp_seq("root", 0, nullptr)
+ : simgrid::sd::Task::create_comp_par_amdahl("root", 0, nullptr, 0));
else
root = jobs.at("root");
- SD_task_set_state(root, SD_SCHEDULABLE); /* by design the root task is always SCHEDULABLE */
+ root->set_state(SD_SCHEDULABLE); /* by design the root task is always SCHEDULABLE */
xbt_dynar_insert_at(result, 0, &root); /* Put it at the beginning of the dynar */
if (jobs.find("end") == jobs.end())
- end = (sequential ? SD_task_create_comp_seq("end", nullptr, 0)
- : SD_task_create_comp_par_amdahl("end", nullptr, 0, 0));
+ end = (sequential ? simgrid::sd::Task::create_comp_seq("end", 0, nullptr)
+ : simgrid::sd::Task::create_comp_par_amdahl("end", 0, nullptr, 0));
else
end = jobs.at("end");
/* Create edges */
- xbt_dynar_t edges = xbt_dynar_new(sizeof(Agedge_t*), nullptr);
+ std::vector<Agedge_t*> edges;
for (node = agfstnode(dag_dot); node; node = agnxtnode(dag_dot, node)) {
- Agedge_t * edge;
- xbt_dynar_reset(edges);
- for (edge = agfstout(dag_dot, node); edge; edge = agnxtout(dag_dot, edge))
- xbt_dynar_push_as(edges, Agedge_t *, edge);
+ edges.clear();
+ for (Agedge_t* edge = agfstout(dag_dot, node); edge; edge = agnxtout(dag_dot, edge))
+ edges.push_back(edge);
/* Be sure edges are sorted */
- xbt_dynar_sort(edges, edge_compare);
+ std::sort(edges.begin(), edges.end(), [](const Agedge_t* a, const Agedge_t* b) { return AGSEQ(a) < AGSEQ(b); });
- xbt_dynar_foreach(edges, i, edge) {
- char *src_name=agnameof(agtail(edge));
- char *dst_name=agnameof(aghead(edge));
+ for (Agedge_t* edge : edges) {
+ const char* src_name = agnameof(agtail(edge));
+ const char* dst_name = agnameof(aghead(edge));
double size = atof(agget(edge, (char *) "size"));
SD_task_t src = jobs.at(src_name);
XBT_DEBUG("See <transfer id=%s amount = %.0f>", name.c_str(), size);
if (jobs.find(name) == jobs.end()) {
if (sequential)
- task = SD_task_create_comm_e2e(name.c_str(), nullptr, size);
+ task = simgrid::sd::Task::create_comm_e2e(name.c_str(), size, nullptr);
else
- task = SD_task_create_comm_par_mxn_1d_block(name.c_str(), nullptr, size);
- SD_task_dependency_add(nullptr, nullptr, src, task);
- SD_task_dependency_add(nullptr, nullptr, task, dst);
+ task = simgrid::sd::Task::create_comm_par_mxn_1d_block(name.c_str(), size, nullptr);
+ SD_task_dependency_add(src, task);
+ SD_task_dependency_add(task, dst);
jobs.insert({name, task});
xbt_dynar_push(result, &task);
} else {
XBT_WARN("Task '%s' is defined more than once", name.c_str());
}
} else {
- SD_task_dependency_add(nullptr, nullptr, src, dst);
+ SD_task_dependency_add(src, dst);
}
}
}
- xbt_dynar_free(&edges);
- XBT_DEBUG("All tasks have been created, put %s at the end of the dynar", end->name);
+ XBT_DEBUG("All tasks have been created, put %s at the end of the dynar", end->get_cname());
xbt_dynar_push(result, &end);
/* Connect entry tasks to 'root', and exit tasks to 'end'*/
+ unsigned i;
xbt_dynar_foreach (result, i, task){
- if (task->predecessors->empty() && task->inputs->empty() && task != root) {
- XBT_DEBUG("Task '%s' has no source. Add dependency from 'root'", task->name);
- SD_task_dependency_add(nullptr, nullptr, root, task);
+ if (task->has_unsolved_dependencies() == 0 && task != root) {
+ XBT_DEBUG("Task '%s' has no source. Add dependency from 'root'", task->get_cname());
+ SD_task_dependency_add(root, task);
}
- if (task->successors->empty() && task->outputs->empty() && task != end) {
- XBT_DEBUG("Task '%s' has no destination. Add dependency to 'end'", task->name);
- SD_task_dependency_add(nullptr, nullptr, task, end);
+ if (task->is_waited_by() == 0 && task != end) {
+ XBT_DEBUG("Task '%s' has no destination. Add dependency to 'end'", task->get_cname());
+ SD_task_dependency_add(task, end);
}
}
fclose(in_file);
if(schedule){
- char *computer_name;
if (schedule_success) {
- const sg_host_t *workstations = sg_host_list ();
- xbt_dict_foreach(computers,dict_cursor,computer_name,computer){
+ std::vector<simgrid::s4u::Host*> hosts = simgrid::s4u::Engine::get_instance()->get_all_hosts();
+
+ for (auto const& elm : computers) {
SD_task_t previous_task = nullptr;
- xbt_dynar_foreach(computer, i, task){
+ for (auto const& cur_task : *elm.second) {
/* add dependency between the previous and the task to avoid parallel execution */
- if(task){
- if (previous_task && not SD_task_dependency_exists(previous_task, task))
- SD_task_dependency_add(nullptr, nullptr, previous_task, task);
+ if (cur_task) {
+ if (previous_task && not SD_task_dependency_exists(previous_task, cur_task))
+ SD_task_dependency_add(previous_task, cur_task);
- SD_task_schedulel(task, 1, workstations[atoi(computer_name)]);
- previous_task = task;
+ cur_task->schedulev({hosts[std::stoi(elm.first)]});
+ previous_task = cur_task;
}
}
- xbt_dynar_free(&computer);
+ delete elm.second;
}
} else {
XBT_WARN("The scheduling is ignored");
- xbt_dict_foreach(computers,dict_cursor,computer_name,computer)
- xbt_dynar_free(&computer);
+ for (auto const& elm : computers)
+ delete elm.second;
xbt_dynar_free(&result);
result = nullptr;
}
}
- xbt_dict_free(&computers);
-
if (result && not acyclic_graph_detail(result)) {
- char* base = xbt_basename(filename);
- XBT_ERROR("The DOT described in %s is not a DAG. It contains a cycle.", base);
- free(base);
+ std::string base = simgrid::xbt::Path(filename).get_base_name();
+ XBT_ERROR("The DOT described in %s is not a DAG. It contains a cycle.", base.c_str());
xbt_dynar_free(&result);
result = nullptr;
}