+/* Copyright (c) 2006, 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. */
+
#ifndef SIMDAG_DATATYPES_H
#define SIMDAG_DATATYPES_H
@see SD_workstation_management */
typedef struct SD_workstation *SD_workstation_t;
+/** @brief Workstation access mode
+ @ingroup SD_datatypes_management
+
+ By default, a workstation resource is shared, i.e. several tasks
+ can be executed at the same time on a workstation. The CPU power of
+ the workstation is shared between the running tasks on the workstation.
+ In sequential mode, only one task can use the workstation, and the other
+ tasks wait in a FIFO.
+
+ @see SD_workstation_get_access_mode(), SD_workstation_set_access_mode() */
+typedef enum {
+ SD_WORKSTATION_SHARED_ACCESS, /**< @brief Several tasks can be executed at the same time */
+ SD_WORKSTATION_SEQUENTIAL_ACCESS /**< @brief Only one task can be executed, the others wait in a FIFO. */
+} e_SD_workstation_access_mode_t;
+
+typedef enum {
+ SD_LINK_SHARED,
+ SD_LINK_FATPIPE
+} e_SD_link_sharing_policy_t;
+
/** @brief Link datatype
@ingroup SD_datatypes_management
A task is some <em>computing amount</em> that can be executed
in parallel on several workstations. A task may depend on other
tasks, this means that the task cannot start until the other tasks are done.
- Each task has a <em>\ref e_SD_task_state_t "state"</em> indicating whether the task is scheduled, running, done, etc.
+ Each task has a <em>\ref e_SD_task_state_t "state"</em> indicating whether
+ the task is scheduled, running, done, etc.
@see SD_task_management */
typedef struct SD_task *SD_task_t;
@see SD_task_management */
typedef enum {
SD_NOT_SCHEDULED = 0, /**< @brief Initial state (not valid for SD_watch and SD_unwatch). */
- SD_SCHEDULED = 0x0001, /**< @brief A task becomes SD_SCHEDULED when you call function
- SD_task_schedule. SD_simulate will execute it when it becomes SD_READY. */
- SD_READY = 0x0002, /**< @brief A scheduled task becomes ready as soon as its dependencies are satisfied. */
- SD_RUNNING = 0x0004, /**< @brief When a task is ready, it is launched in the function SD_simulate and becomes SD_RUNNING. */
- SD_DONE = 0x0008, /**< @brief The task is successfuly finished. */
- SD_FAILED = 0x0010 /**< @brief A problem occured during the execution of the task. */
+ SD_SCHEDULABLE = 0x0001, /**< @brief A task becomes SD_READY as soon as its dependencies are satisfied */
+ SD_SCHEDULED = 0x0002, /**< @brief A task becomes SD_SCHEDULED when you call function
+ SD_task_schedule. SD_simulate will execute it when it becomes SD_RUNNABLE. */
+ SD_RUNNABLE = 0x0004, /**< @brief A scheduled task becomes runnable is SD_simulate as soon as its dependencies are satisfied. */
+ SD_IN_FIFO = 0x0008, /**< @brief A runnable task can have to wait in a workstation fifo if the workstation is sequential */
+ SD_RUNNING = 0x0010, /**< @brief An SD_RUNNABLE or SD_IN_FIFO becomes SD_RUNNING when it is launched. */
+ SD_DONE = 0x0020, /**< @brief The task is successfully finished. */
+ SD_FAILED = 0x0040 /**< @brief A problem occurred during the execution of the task. */
} e_SD_task_state_t;
+/** @brief Task kinds
+ @ingroup SD_datatypes_management
+
+ @see SD_task_management */
+typedef enum {
+ SD_TASK_NOT_TYPED = 0, /**< @brief no specified type */
+ SD_TASK_COMM_E2E = 1, /**< @brief end to end communication */
+ SD_TASK_COMP_SEQ = 2, /**< @brief sequential computation */
+ SD_TASK_COMP_PAR_AMDAHL = 3 /**< @brief parallel computation (Amdahl's law) */
+} e_SD_task_kind_t;
+
+
#endif