1 /* Copyright (c) 2004-2015. The SimGrid Team.
2 * All rights reserved. */
4 /* This program is free software; you can redistribute it and/or modify it
5 * under the terms of the license (GNU LGPL) which comes with this package. */
7 #include "msg_private.h"
8 #include "src/simix/smx_private.h"
9 #include "xbt/sysdep.h"
12 /** @addtogroup m_task_management
14 * Since most scheduling algorithms rely on a concept of task that can be either <em>computed</em> locally or
15 * <em>transferred</em> on another processor, it seems to be the right level of abstraction for our purposes.
16 * A <em>task</em> may then be defined by a <em>computing amount</em>, a <em>message size</em> and
17 * some <em>private data</em>.
20 XBT_LOG_NEW_DEFAULT_SUBCATEGORY(msg_task, msg, "Logging specific to MSG (task)");
22 /********************************* Task **************************************/
23 /** \ingroup m_task_management
24 * \brief Creates a new #msg_task_t.
26 * A constructor for #msg_task_t taking four arguments and returning the corresponding object.
27 * \param name a name for the object. It is for user-level information and can be NULL.
28 * \param flop_amount a value of the processing amount (in flop) needed to process this new task.
29 * If 0, then it cannot be executed with MSG_task_execute(). This value has to be >=0.
30 * \param message_size a value of the amount of data (in bytes) needed to transfer this new task. If 0, then it cannot
31 * be transfered with MSG_task_send() and MSG_task_recv(). This value has to be >=0.
32 * \param data a pointer to any data may want to attach to the new object. It is for user-level information and can
33 * be NULL. It can be retrieved with the function \ref MSG_task_get_data.
35 * \return The new corresponding object.
37 msg_task_t MSG_task_create(const char *name, double flop_amount, double message_size, void *data)
39 msg_task_t task = xbt_new(s_msg_task_t, 1);
40 simdata_task_t simdata = xbt_new(s_simdata_task_t, 1);
41 task->simdata = simdata;
44 task->name = xbt_strdup(name);
48 simdata->compute = NULL;
50 simdata->bytes_amount = message_size;
51 simdata->flops_amount = flop_amount;
52 simdata->sender = NULL;
53 simdata->receiver = NULL;
54 simdata->source = NULL;
55 simdata->priority = 1.0;
57 simdata->affinity_mask_db = xbt_dict_new_homogeneous(NULL);
62 simdata->host_list = NULL;
63 simdata->flops_parallel_amount = NULL;
64 simdata->bytes_parallel_amount = NULL;
65 TRACE_msg_task_create(task);
70 /** \ingroup m_task_management
71 * \brief Creates a new #msg_task_t (a parallel one....).
73 * A constructor for #msg_task_t taking six arguments and returning the corresponding object.
74 * \param name a name for the object. It is for user-level information and can be NULL.
75 * \param host_nb the number of hosts implied in the parallel task.
76 * \param host_list an array of \p host_nb msg_host_t.
77 * \param flops_amount an array of \p host_nb doubles.
78 * flops_amount[i] is the total number of operations that have to be performed on host_list[i].
79 * \param bytes_amount an array of \p host_nb* \p host_nb doubles.
80 * \param data a pointer to any data may want to attach to the new object.
81 * It is for user-level information and can be NULL.
82 * It can be retrieved with the function \ref MSG_task_get_data.
84 * \return The new corresponding object.
86 msg_task_t MSG_parallel_task_create(const char *name, int host_nb, const msg_host_t * host_list,
87 double *flops_amount, double *bytes_amount, void *data)
89 msg_task_t task = MSG_task_create(name, 0, 0, data);
90 simdata_task_t simdata = task->simdata;
93 /* Simulator Data specific to parallel tasks */
94 simdata->host_nb = host_nb;
95 simdata->host_list = xbt_new0(sg_host_t, host_nb);
96 simdata->flops_parallel_amount = flops_amount;
97 simdata->bytes_parallel_amount = bytes_amount;
99 for (i = 0; i < host_nb; i++)
100 simdata->host_list[i] = host_list[i];
105 /*************** Begin GPU ***************/
106 /** \ingroup m_task_management
107 * \brief Creates a new #msg_gpu_task_t.
109 * A constructor for #msg_gpu_task_t taking four arguments and returning a pointer to the new created GPU task.
111 * \param name a name for the object. It is for user-level information and can be NULL.
112 * \param flops_amount a value of the processing amount (in flop)needed to process this new task. If 0, then it cannot
113 * be executed with MSG_gpu_task_execute(). This value has to be >=0.
114 * \param dispatch_latency time in seconds to load this task on the GPU
115 * \param collect_latency time in seconds to transfer result from the GPU back to the CPU (host) when done
117 * \see msg_gpu_task_t
118 * \return The new corresponding object.
120 msg_gpu_task_t MSG_gpu_task_create(const char *name, double flops_amount, double dispatch_latency,
121 double collect_latency)
123 msg_gpu_task_t task = xbt_new(s_msg_gpu_task_t, 1);
124 simdata_gpu_task_t simdata = xbt_new(s_simdata_gpu_task_t, 1);
125 task->simdata = simdata;
127 task->name = xbt_strdup(name);
130 simdata->flops_amount = flops_amount;
131 simdata->dispatch_latency = dispatch_latency;
132 simdata->collect_latency = collect_latency;
134 /* TRACE_msg_gpu_task_create(task); FIXME*/
137 /*************** End GPU ***************/
139 /** \ingroup m_task_management
140 * \brief Return the user data of a #msg_task_t.
142 * This function checks whether \a task is a valid pointer and return the user data associated to \a task if possible.
144 void *MSG_task_get_data(msg_task_t task)
146 xbt_assert((task != NULL), "Invalid parameter");
150 /** \ingroup m_task_management
151 * \brief Sets the user data of a #msg_task_t.
153 * This function allows to associate a new pointer to the user data associated of \a task.
155 void MSG_task_set_data(msg_task_t task, void *data)
157 xbt_assert((task != NULL), "Invalid parameter");
161 /** \ingroup m_task_management
162 * \brief Sets a function to be called when a task has just been copied.
163 * \param callback a callback function
165 void MSG_task_set_copy_callback(void (*callback) (msg_task_t task, msg_process_t sender, msg_process_t receiver)) {
167 msg_global->task_copy_callback = callback;
170 SIMIX_comm_set_copy_data_callback(MSG_comm_copy_data_from_SIMIX);
172 SIMIX_comm_set_copy_data_callback(SIMIX_comm_copy_pointer_callback);
176 /** \ingroup m_task_management
177 * \brief Return the sender of a #msg_task_t.
179 * This functions returns the #msg_process_t which sent this task
181 msg_process_t MSG_task_get_sender(msg_task_t task)
183 xbt_assert(task, "Invalid parameters");
184 return ((simdata_task_t) task->simdata)->sender;
187 /** \ingroup m_task_management
188 * \brief Return the source of a #msg_task_t.
190 * This functions returns the #msg_host_t from which this task was sent
192 msg_host_t MSG_task_get_source(msg_task_t task)
194 xbt_assert(task, "Invalid parameters");
195 return ((simdata_task_t) task->simdata)->source;
198 /** \ingroup m_task_management
199 * \brief Return the name of a #msg_task_t.
201 * This functions returns the name of a #msg_task_t as specified on creation
203 const char *MSG_task_get_name(msg_task_t task)
205 xbt_assert(task, "Invalid parameters");
209 /** \ingroup m_task_management
210 * \brief Sets the name of a #msg_task_t.
212 * This functions allows to associate a name to a task
214 void MSG_task_set_name(msg_task_t task, const char *name)
216 xbt_assert(task, "Invalid parameters");
217 task->name = xbt_strdup(name);
220 /** \ingroup m_task_management
221 * \brief Destroy a #msg_task_t.
223 * Destructor for #msg_task_t. Note that you should free user data, if any, \b before calling this function.
225 * Only the process that owns the task can destroy it.
226 * The owner changes after a successful send.
227 * If a task is successfully sent, the receiver becomes the owner and is supposed to destroy it. The sender should not
229 * If the task failed to be sent, the sender remains the owner of the task.
231 msg_error_t MSG_task_destroy(msg_task_t task)
233 smx_synchro_t action = NULL;
234 xbt_assert((task != NULL), "Invalid parameter");
236 if (task->simdata->isused) {
237 /* the task is being sent or executed: cancel it first */
238 MSG_task_cancel(task);
240 TRACE_msg_task_destroy(task);
242 xbt_free(task->name);
244 action = task->simdata->compute;
246 simcall_execution_destroy(action);
248 /* parallel tasks only */
249 xbt_free(task->simdata->host_list);
251 xbt_dict_free(&task->simdata->affinity_mask_db);
253 /* free main structures */
254 xbt_free(task->simdata);
260 /** \ingroup m_task_usage
261 * \brief Cancel a #msg_task_t.
262 * \param task the task to cancel. If it was executed or transfered, it stops the process that were working on it.
264 msg_error_t MSG_task_cancel(msg_task_t task)
266 xbt_assert((task != NULL), "Cannot cancel a NULL task");
268 if (task->simdata->compute) {
269 simcall_execution_cancel(task->simdata->compute);
271 else if (task->simdata->comm) {
272 simdata_task_t simdata = task->simdata;
273 simcall_comm_cancel(simdata->comm);
274 if (msg_global->debug_multiple_use && simdata->isused!=0)
275 xbt_ex_free(*(xbt_ex_t*)simdata->isused);
281 /** \ingroup m_task_management
282 * \brief Returns the remaining amount of flops needed to execute a task #msg_task_t.
284 * Once a task has been processed, this amount is set to 0. If you want, you can reset this value with
285 * #MSG_task_set_flops_amount before restarting the task.
287 double MSG_task_get_flops_amount(msg_task_t task) {
288 if (task->simdata->compute) {
289 return simcall_execution_get_remains(task->simdata->compute);
291 return task->simdata->flops_amount;
295 /** \ingroup m_task_management
296 * \brief set the computation amount needed to process a task #msg_task_t.
298 * \warning If the computation is ongoing (already started and not finished),
299 * it is not modified by this call. Moreover, after its completion, the ongoing execution with set the flops_amount to
300 * zero, overriding any value set during the execution.
302 void MSG_task_set_flops_amount(msg_task_t task, double flops_amount)
304 task->simdata->flops_amount = flops_amount;
307 /** \ingroup m_task_management
308 * \brief set the amount data attached with a task #msg_task_t.
310 * \warning If the transfer is ongoing (already started and not finished), it is not modified by this call.
312 void MSG_task_set_bytes_amount(msg_task_t task, double data_size)
314 task->simdata->bytes_amount = data_size;
317 /** \ingroup m_task_management
318 * \brief Returns the total amount received by a task #msg_task_t.
319 * If the communication does not exist it will return 0.
320 * So, if the communication has FINISHED or FAILED it returns zero.
322 double MSG_task_get_remaining_communication(msg_task_t task)
324 xbt_assert((task != NULL) && (task->simdata != NULL), "Invalid parameter");
325 XBT_DEBUG("calling simcall_communication_get_remains(%p)", task->simdata->comm);
326 return simcall_comm_get_remains(task->simdata->comm);
329 /** \ingroup m_task_management
330 * \brief Returns the size of the data attached to a task #msg_task_t.
332 double MSG_task_get_bytes_amount(msg_task_t task)
334 xbt_assert((task != NULL) && (task->simdata != NULL), "Invalid parameter");
335 return task->simdata->bytes_amount;
338 /** \ingroup m_task_management
339 * \brief Changes the priority of a computation task. This priority doesn't affect the transfer rate. A priority of 2
340 * will make a task receive two times more cpu power than the other ones.
342 void MSG_task_set_priority(msg_task_t task, double priority)
344 xbt_assert((task != NULL) && (task->simdata != NULL), "Invalid parameter");
345 task->simdata->priority = 1 / priority;
346 if (task->simdata->compute)
347 simcall_execution_set_priority(task->simdata->compute,
348 task->simdata->priority);
351 /** \ingroup m_task_management
352 * \brief Changes the maximum CPU utilization of a computation task.
355 * For VMs, there is a pitfall. Please see MSG_vm_set_bound().
357 void MSG_task_set_bound(msg_task_t task, double bound)
359 xbt_assert(task, "Invalid parameter");
360 xbt_assert(task->simdata, "Invalid parameter");
363 XBT_INFO("bound == 0 means no capping (i.e., unlimited).");
365 task->simdata->bound = bound;
366 if (task->simdata->compute)
367 simcall_execution_set_bound(task->simdata->compute, task->simdata->bound);
370 /** \ingroup m_task_management
371 * \brief Changes the CPU affinity of a computation task.
373 * When pinning the given task to the first CPU core of the given host, use 0x01 for the mask value. Each bit of the
374 * mask value corresponds to each CPU core. See taskset(1) on Linux.
376 * \param task a target task
377 * \param host the host having a multi-core CPU
378 * \param mask the bit mask of a new CPU affinity setting for the task
381 * 0. Define a host with multiple cores.
382 * \<host id="PM0" power="1E8" core="2"/\>
384 * 1. Pin a given task to the first CPU core of a host.
385 * MSG_task_set_affinity(task, pm0, 0x01);
387 * 2. Pin a given task to the third CPU core of a host. Turn on the third bit of the mask.
388 * MSG_task_set_affinity(task, pm0, 0x04); // 0x04 == 100B
390 * 3. Pin a given VM to the first CPU core of a host.
391 * MSG_vm_set_affinity(vm, pm0, 0x01);
393 * See examples/msg/cloud/multicore.c for more information.
396 * 1. The current code does not allow an affinity of a task to multiple cores.
397 * The mask value 0x03 (i.e., a given task will be executed on the first core or the second core) is not allowed.
398 * The mask value 0x01 or 0x02 works. See cpu_cas01.c for details.
400 * 2. It is recommended to first compare simulation results in both the Lazy and Full calculation modes
401 * (using --cfg=cpu/optim:Full or not). Fix cpu_cas01.c if you find wrong results in the Lazy mode.
403 void MSG_task_set_affinity(msg_task_t task, msg_host_t host, unsigned long mask)
405 xbt_assert(task, "Invalid parameter");
406 xbt_assert(task->simdata, "Invalid parameter");
410 /* We need remove_ext() not throwing exception. */
411 void *ret = xbt_dict_get_or_null_ext(task->simdata->affinity_mask_db, (char *) host, sizeof(msg_host_t));
413 xbt_dict_remove_ext(task->simdata->affinity_mask_db, (char *) host, sizeof(host));
415 xbt_dict_set_ext(task->simdata->affinity_mask_db, (char *) host, sizeof(host), (void *)(uintptr_t) mask, NULL);
417 /* We set affinity data of this task. If the task is being executed, we actually change the affinity setting of the
418 * task. Otherwise, this change will be applied when the task is executed. */
419 if (!task->simdata->compute) {
420 /* task is not yet executed */
421 XBT_INFO("set affinity(0x%04lx@%s) for %s (not active now)", mask, MSG_host_get_name(host),
422 MSG_task_get_name(task));
427 smx_synchro_t compute = task->simdata->compute;
428 msg_host_t host_now = compute->execution.host; // simix_private.h is necessary
429 if (host_now != host) {
430 /* task is not yet executed on this host */
431 XBT_INFO("set affinity(0x%04lx@%s) for %s (not active now)", mask, MSG_host_get_name(host),
432 MSG_task_get_name(task));
436 /* task is being executed on this host. so change the affinity now */
438 /* check it works. remove me if it works. */
439 xbt_assert((unsigned long)(uintptr_t) xbt_dict_get_or_null_ext(task->simdata->affinity_mask_db,
440 (char *) host, sizeof(msg_host_t)) == mask);
443 XBT_INFO("set affinity(0x%04lx@%s) for %s", mask, MSG_host_get_name(host), MSG_task_get_name(task));
444 simcall_execution_set_affinity(task->simdata->compute, host, mask);