-/* Copyright (c) 2009-2016. The SimGrid Team.
+/* Copyright (c) 2009-2017. 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 "src/simdag/simdag_private.h"
+#include "simdag_private.hpp"
#include "simgrid/simdag.h"
-#include "xbt/misc.h"
+#include "xbt/file.h" /* xbt_basename() */
#include "xbt/log.h"
+#include "xbt/misc.h"
#include "xbt/str.h"
-#include "xbt/file.h" /* xbt_basename() */
+#include <unordered_map>
XBT_LOG_NEW_DEFAULT_SUBCATEGORY(sd_daxparse, sd, "Parsing DAX files");
}
/* Ensure that transfer tasks have unique names even though a file is used several times */
-
void uniq_transfer_task_name(SD_task_t task)
{
SD_task_t child = *(task->successors->begin());
SD_task_t parent = *(task->predecessors->begin());
- char *new_name = bprintf("%s_%s_%s", SD_task_get_name(parent), SD_task_get_name(task), SD_task_get_name(child));
-
- SD_task_set_name(task, new_name);
+ std::string new_name =
+ std::string(SD_task_get_name(parent)) + "_" + SD_task_get_name(task) + "_" + SD_task_get_name(child);
- free(new_name);
+ SD_task_set_name(task, new_name.c_str());
}
static bool children_are_marked(SD_task_t task){
- for (std::set<SD_task_t>::iterator it=task->successors->begin(); it!=task->successors->end(); ++it)
- if ((*it)->marked == 0)
+ for (SD_task_t it : *task->successors)
+ if (it->marked == 0)
return false;
- for (std::set<SD_task_t>::iterator it=task->outputs->begin(); it!=task->outputs->end(); ++it)
- if ((*it)->marked == 0)
+ for (SD_task_t it : *task->outputs)
+ if (it->marked == 0)
return false;
return true;
}
static bool parents_are_marked(SD_task_t task){
- for (std::set<SD_task_t>::iterator it=task->predecessors->begin(); it!=task->predecessors->end(); ++it)
- if ((*it)->marked == 0)
+ for (SD_task_t it : *task->predecessors)
+ if (it->marked == 0)
return false;
- for (std::set<SD_task_t>::iterator it=task->inputs->begin(); it!=task->inputs->end(); ++it)
- if ((*it)->marked == 0)
+ for (SD_task_t it : *task->inputs)
+ if (it->marked == 0)
return false;
return true;
}
bool acyclic_graph_detail(xbt_dynar_t dag){
- unsigned int count, count_current=0;
+ unsigned int count;
bool all_marked = true;
SD_task_t task = nullptr;
- xbt_dynar_t next = nullptr, current = xbt_dynar_new(sizeof(SD_task_t),nullptr);
-
+ std::vector<SD_task_t> current;
xbt_dynar_foreach(dag,count,task){
- if(task->kind == SD_TASK_COMM_E2E) continue;
- task->marked = 0;
- if(task->successors->empty() && task->outputs->empty())
- xbt_dynar_push(current, &task);
+ if(task->kind != SD_TASK_COMM_E2E){
+ task->marked = 0;
+ if(task->successors->empty() && task->outputs->empty())
+ current.push_back(task);
+ }
}
- //test if something has to be done for the next iteration
- while(!xbt_dynar_is_empty(current)){
- next = xbt_dynar_new(sizeof(SD_task_t),nullptr);
- //test if the current iteration is done
- xbt_dynar_foreach(current,count_current,task){
- if (task == nullptr)
- continue;
- //push task in next
- task->marked = 1;
- for (std::set<SD_task_t>::iterator it=task->inputs->begin(); it!=task->inputs->end(); ++it){
- (*it)->marked = 1;
+ while (not current.empty()) {
+ std::vector<SD_task_t> next;
+ for (auto t: current){
+ //Mark task
+ t->marked = 1;
+ for (SD_task_t input : *t->inputs){
+ input->marked=1;
// Inputs are communication, hence they can have only one predecessor
- SD_task_t input_pred = *((*it)->predecessors->begin());
+ SD_task_t input_pred = *(input->predecessors->begin());
if (children_are_marked(input_pred))
- xbt_dynar_push(next, &input_pred);
+ next.push_back(input_pred);
}
- for (std::set<SD_task_t>::iterator it=task->predecessors->begin(); it!=task->predecessors->end(); ++it){
- if (children_are_marked(*it))
- xbt_dynar_push(next, &(*it));
+ for (SD_task_t pred : *t->predecessors) {
+ if (children_are_marked(pred))
+ next.push_back(pred);
}
}
- xbt_dynar_free(¤t);
+ current.clear();
current = next;
- next = nullptr;
}
- xbt_dynar_free(¤t);
+
all_marked = true;
+ //test if all tasks are marked
xbt_dynar_foreach(dag,count,task){
- if(task->kind == SD_TASK_COMM_E2E)
- continue;
- //test if all tasks are marked
- if(task->marked == 0){
+ if(task->kind != SD_TASK_COMM_E2E && task->marked == 0){
XBT_WARN("the task %s is not marked",task->name);
all_marked = false;
break;
}
}
- if(!all_marked){
- XBT_VERB("there is at least one cycle in your task graph");
-
- current = xbt_dynar_new(sizeof(SD_task_t),nullptr);
- xbt_dynar_foreach(dag,count,task){
- if(task->kind == SD_TASK_COMM_E2E)
- continue;
- if(task->predecessors->empty() && task->inputs->empty()){
- xbt_dynar_push(current, &task);
- }
- }
+ if (not all_marked) {
+ XBT_VERB("there is at least one cycle in your task graph");
xbt_dynar_foreach(dag,count,task){
- if(task->kind == SD_TASK_COMM_E2E)
- continue;
- if(task->predecessors->empty() && task->inputs->empty()){
+ if(task->kind != SD_TASK_COMM_E2E && task->predecessors->empty() && task->inputs->empty()){
task->marked = 1;
- xbt_dynar_push(current, &task);
+ current.push_back(task);
}
}
//test if something has to be done for the next iteration
- while(!xbt_dynar_is_empty(current)){
- next = xbt_dynar_new(sizeof(SD_task_t),nullptr);
+ while (not current.empty()) {
+ std::vector<SD_task_t> next;
//test if the current iteration is done
- xbt_dynar_foreach(current,count_current,task){
- if (task == nullptr)
- continue;
- //push task in next
- task->marked = 1;
- for (std::set<SD_task_t>::iterator it=task->outputs->begin(); it!=task->outputs->end(); ++it){
- (*it)->marked = 1;
+ for (auto t: current){
+ t->marked = 1;
+ for (SD_task_t output : *t->outputs) {
+ output->marked = 1;
// outputs are communication, hence they can have only one successor
- SD_task_t output_succ = *((*it)->successors->begin());
+ SD_task_t output_succ = *(output->successors->begin());
if (parents_are_marked(output_succ))
- xbt_dynar_push(next, &output_succ);
+ next.push_back(output_succ);
}
- for (std::set<SD_task_t>::iterator it=task->predecessors->begin(); it!=task->predecessors->end(); ++it){
- if (parents_are_marked(*it))
- xbt_dynar_push(next, &(*it));
+ for (SD_task_t succ : *t->successors) {
+ if (parents_are_marked(succ))
+ next.push_back(succ);
}
- xbt_dynar_free(¤t);
+ current.clear();
current = next;
- next = nullptr;
}
- xbt_dynar_free(¤t);
- all_marked = true;
- xbt_dynar_foreach(dag,count,task){
- if(task->kind == SD_TASK_COMM_E2E)
- continue;
- //test if all tasks are marked
- if(task->marked == 0){
- XBT_WARN("the task %s is in a cycle",task->name);
- all_marked = false;
- }
+ }
+
+ all_marked = true;
+ xbt_dynar_foreach(dag,count,task){
+ if(task->kind != SD_TASK_COMM_E2E && task->marked == 0){
+ XBT_WARN("the task %s is in a cycle",task->name);
+ all_marked = false;
}
}
}
static YY_BUFFER_STATE input_buffer;
static xbt_dynar_t result;
-static xbt_dict_t jobs;
+static std::unordered_map<std::string, SD_task_t> jobs;
static xbt_dict_t files;
static SD_task_t current_job;
-static SD_task_t root_task, end_task;
+static SD_task_t root_task;
+static SD_task_t end_task;
static void dax_task_free(void *task)
{
}
/** @brief loads a DAX file describing a DAG
- *
+ *
* See https://confluence.pegasus.isi.edu/display/pegasus/WorkflowGenerator for more details.
*/
xbt_dynar_t SD_daxload(const char *filename)
{
xbt_dict_cursor_t cursor;
SD_task_t file;
- char *name;
- FILE *in_file = fopen(filename, "r");
+ char* name;
+ FILE* in_file = fopen(filename, "r");
xbt_assert(in_file, "Unable to open \"%s\"\n", filename);
input_buffer = dax__create_buffer(in_file, 10);
dax__switch_to_buffer(input_buffer);
result = xbt_dynar_new(sizeof(SD_task_t), dax_task_free);
files = xbt_dict_new_homogeneous(&dax_task_free);
- jobs = xbt_dict_new_homogeneous(nullptr);
root_task = SD_task_create_comp_seq("root", nullptr, 0);
/* by design the root task is always SCHEDULABLE */
SD_task_set_state(root_task, SD_SCHEDULABLE);
dax__delete_buffer(input_buffer);
fclose(in_file);
dax_lex_destroy();
- xbt_dict_free(&jobs);
/* And now, post-process the files.
* We want a file task per pair of computation tasks exchanging the file. Duplicate on need
xbt_dict_foreach(files, cursor, name, file) {
SD_task_t newfile;
if (file->predecessors->empty()) {
- for (std::set<SD_task_t>::iterator it=file->successors->begin(); it!=file->successors->end(); ++it){
+ for (SD_task_t it : *file->successors) {
newfile = SD_task_create_comm_e2e(file->name, nullptr, file->amount);
SD_task_dependency_add(nullptr, nullptr, root_task, newfile);
- SD_task_dependency_add(nullptr, nullptr, newfile, (*it));
+ SD_task_dependency_add(nullptr, nullptr, newfile, it);
xbt_dynar_push(result, &newfile);
}
} else if (file->successors->empty()) {
- for (std::set<SD_task_t>::iterator it=file->predecessors->begin(); it!=file->predecessors->end(); ++it){
+ for (SD_task_t it : *file->predecessors){
newfile = SD_task_create_comm_e2e(file->name, nullptr, file->amount);
- SD_task_dependency_add(nullptr, nullptr, (*it), newfile);
+ SD_task_dependency_add(nullptr, nullptr, it, newfile);
SD_task_dependency_add(nullptr, nullptr, newfile, end_task);
xbt_dynar_push(result, &newfile);
}
} else {
- for (std::set<SD_task_t>::iterator it=file->predecessors->begin(); it!=file->predecessors->end(); ++it){
- for (std::set<SD_task_t>::iterator it2=file->successors->begin(); it2!=file->successors->end(); ++it2){
- if (*it == *it2) {
+ for (SD_task_t it : *file->predecessors) {
+ for (SD_task_t it2 : *file->successors) {
+ if (it == it2) {
XBT_WARN ("File %s is produced and consumed by task %s."
- "This loop dependency will prevent the execution of the task.", file->name, (*it)->name);
+ "This loop dependency will prevent the execution of the task.", file->name, it->name);
}
newfile = SD_task_create_comm_e2e(file->name, nullptr, file->amount);
- SD_task_dependency_add(nullptr, nullptr, (*it), newfile);
- SD_task_dependency_add(nullptr, nullptr, newfile, (*it2));
+ SD_task_dependency_add(nullptr, nullptr, it, newfile);
+ SD_task_dependency_add(nullptr, nullptr, newfile, it2);
xbt_dynar_push(result, &newfile);
}
}
/* If some tasks do not take files as input, connect them to the root
* if they don't produce files, connect them to the end node.
*/
- if ((file != root_task) && file->inputs->empty())
- SD_task_dependency_add(nullptr, nullptr, root_task, file);
- if ((file != end_task) && file->outputs->empty())
- SD_task_dependency_add(nullptr, nullptr, file, end_task);
+ if ((file != root_task) && (file != end_task)) {
+ if (file->inputs->empty())
+ SD_task_dependency_add(nullptr, nullptr, root_task, file);
+ if (file->outputs->empty())
+ SD_task_dependency_add(nullptr, nullptr, file, end_task);
+ }
} else {
- THROW_IMPOSSIBLE;
+ THROW_IMPOSSIBLE;
}
}
- if (!acyclic_graph_detail(result)) {
+ if (not acyclic_graph_detail(result)) {
char* base = xbt_basename(filename);
XBT_ERROR("The DAX described in %s is not a DAG. It contains a cycle.", base);
free(base);
void STag_dax__adag()
{
- XBT_ATTRIB_UNUSED double version;
- version = xbt_str_parse_double(A_dax__adag_version, "Parse error: %s is not a double");
-
- xbt_assert(version == 2.1, "Expected version 2.1 in <adag> tag, got %f. Fix the parser or your file", version);
+ try {
+ double version = std::stod(std::string(A_dax__adag_version));
+ xbt_assert(version == 2.1, "Expected version 2.1 in <adag> tag, got %f. Fix the parser or your file", version);
+ } catch (std::invalid_argument& ia) {
+ throw std::invalid_argument(std::string("Parse error: ") + A_dax__adag_version + " is not a double");
+ }
}
void STag_dax__job()
{
- double runtime = xbt_str_parse_double(A_dax__job_runtime, "Parse error: %s is not a double");
- char *name = bprintf("%s@%s", A_dax__job_id, A_dax__job_name);
- runtime *= 4200000000.; /* Assume that timings were done on a 4.2GFlops machine. I mean, why not? */
- XBT_DEBUG("See <job id=%s runtime=%s %.0f>",A_dax__job_id,A_dax__job_runtime,runtime);
- current_job = SD_task_create_comp_seq(name, nullptr, runtime);
- xbt_dict_set(jobs, A_dax__job_id, current_job, nullptr);
- free(name);
- xbt_dynar_push(result, ¤t_job);
+ try {
+ double runtime = std::stod(std::string(A_dax__job_runtime));
+
+ std::string name = std::string(A_dax__job_id) + "@" + A_dax__job_name;
+ runtime *= 4200000000.; /* Assume that timings were done on a 4.2GFlops machine. I mean, why not? */
+ XBT_DEBUG("See <job id=%s runtime=%s %.0f>", A_dax__job_id, A_dax__job_runtime, runtime);
+ current_job = SD_task_create_comp_seq(name.c_str(), nullptr, runtime);
+ jobs.insert({A_dax__job_id, current_job});
+ xbt_dynar_push(result, ¤t_job);
+ } catch (std::invalid_argument& ia) {
+ throw std::invalid_argument(std::string("Parse error: ") + A_dax__job_runtime + " is not a double");
+ }
}
-void STag_dax__uses(void)
+void STag_dax__uses()
{
- double size = xbt_str_parse_double(A_dax__uses_size, "Parse error: %s is not a double");
- int is_input = (A_dax__uses_link == A_dax__uses_link_input);
+ double size;
+ try {
+ size = std::stod(std::string(A_dax__uses_size));
+ } catch (std::invalid_argument& ia) {
+ throw std::invalid_argument(std::string("Parse error: ") + A_dax__uses_size + " is not a double");
+ }
+ bool is_input = (A_dax__uses_link == A_dax__uses_link_input);
XBT_DEBUG("See <uses file=%s %s>",A_dax__uses_file,(is_input?"in":"out"));
SD_task_t file = static_cast<SD_task_t>(xbt_dict_get_or_null(files, A_dax__uses_file));
sd_global->initial_tasks->erase(file);
xbt_dict_set(files, A_dax__uses_file, file, nullptr);
} else {
- if (SD_task_get_amount(file) != size) {
+ if (file->amount < size || file->amount > size) {
XBT_WARN("Ignore file %s size redefinition from %.0f to %.0f", A_dax__uses_file, SD_task_get_amount(file), size);
}
}
static SD_task_t current_child;
void STag_dax__child()
{
- current_child = static_cast<SD_task_t>(xbt_dict_get_or_null(jobs, A_dax__child_ref));
- xbt_assert(current_child != nullptr,"Parse error on line %d: Asked to add dependencies to the non-existent %s task",
- dax_lineno, A_dax__child_ref);
+ auto job = jobs.find(A_dax__child_ref);
+ if (job != jobs.end()) {
+ current_child = job->second;
+ } else {
+ throw std::out_of_range(std::string("Parse error on line ") + std::to_string(dax_lineno) +
+ ": Asked to add dependencies to the non-existent " + A_dax__child_ref + "task");
+ }
}
void ETag_dax__child()
void STag_dax__parent()
{
- SD_task_t parent = static_cast<SD_task_t>(xbt_dict_get_or_null(jobs, A_dax__parent_ref));
- xbt_assert(parent != nullptr, "Parse error on line %d: Asked to add a dependency from %s to %s, but %s does not exist",
- dax_lineno, current_child->name, A_dax__parent_ref, A_dax__parent_ref);
- SD_task_dependency_add(nullptr, nullptr, parent, current_child);
- XBT_DEBUG("Control-flow dependency from %s to %s", current_child->name, parent->name);
+ auto job = jobs.find(A_dax__parent_ref);
+ if (job != jobs.end()) {
+ SD_task_t parent = job->second;
+ SD_task_dependency_add(nullptr, nullptr, parent, current_child);
+ XBT_DEBUG("Control-flow dependency from %s to %s", current_child->name, parent->name);
+ } else {
+ throw std::out_of_range(std::string("Parse error on line ") + std::to_string(dax_lineno) +
+ ": Asked to add a dependency from " + current_child->name + " to " + A_dax__parent_ref +
+ ", but " + A_dax__parent_ref + " does not exist");
+ }
}
void ETag_dax__adag()
XBT_DEBUG("See </adag>");
}
-void ETag_dax__job(void)
+void ETag_dax__job()
{
current_job = nullptr;
XBT_DEBUG("See </job>");
}
-void ETag_dax__parent(void)
+void ETag_dax__parent()
{
XBT_DEBUG("See </parent>");
}
-void ETag_dax__uses(void)
+void ETag_dax__uses()
{
XBT_DEBUG("See </uses>");
}