/*! \page examples SimGrid Examples
-\note
- This page is under work -- sorry for the inconvenience (FIXME).
-
-- @ref help
-
\tableofcontents
SimGrid comes with many examples provided in the examples/ directory.
-Those examples are described in section \ref MSG_examples. Those
+Those examples are described in section \ref msg_examples. Those
examples are commented and should be easy to understand. for a first
step into SimGrid we also provide some more detailed examples in the
sections below.
\htmlonly
-You should also check our online <a href="http://simgrid.gforge.inria.fr/tutorials.html"> tutorial section</a> that contains a generic tutorial about using SimGrid.
+You should also check our online <a href="http://simgrid.gforge.inria.fr/documentation.html"> tutorial section</a> that contains a generic tutorial about using SimGrid.
\endhtmlonly
\section using_msg Using MSG
\htmlonly
-You should also check our online <a href="http://simgrid.gforge.inria.fr/tutorials.html"> tutorial section</a> that contains a dedicated tutorial.
+You should also check our online <a href="http://simgrid.gforge.inria.fr/documentation.html"> tutorial section</a> that contains a dedicated tutorial.
\endhtmlonly
Here are some examples on how to use MSG, the most used API.
\subsection MSG_ex_basics Basic examples and features
-\subsubsection MSG_ex_asynchronous_communications Asynchronous communications
+\subsubsection MSG_ex_master_worker Basic Master/Workers
+Simulation of a master-worker application using a realistic platform and an external description of the deployment.
-Simulation of asynchronous communications between a sender and a receiver using a realistic platform and
-an external description of the deployment.
+\paragraph MSG_ex_mw_TOC Table of contents:
- - \ref MSG_ext_icomms_code
- - \ref MSG_ext_icomms_preliminary
- - \ref MSG_ext_icomms_Sender
- - \ref MSG_ext_icomms_Receiver
- - \ref MSG_ext_icomms_core
- - \ref MSG_ext_icomms_Main
- - \ref MSG_ext_icomms_fct_Waitall
- - \ref MSG_ext_icomms_fct_Waitany
+ - \ref MSG_ext_mw_preliminary
+ - \ref MSG_ext_mw_master
+ - \ref MSG_ext_mw_worker
+ - \ref MSG_ext_mw_core
+ - \ref MSG_ext_mw_platform
+ - \ref MSG_ext_mw_application
<hr>
-\dontinclude msg/icomms/peer.c
+\dontinclude msg/app-masterworker/app-masterworker.c
-\paragraph MSG_ext_icomms_code Code of the application
+\paragraph MSG_ext_mw_preliminary Preliminary declarations
-\paragraph MSG_ext_icomms_preliminary Preliminary declarations
\skip include
-\until Sender function
+\until example");
+\skipline Master expects
-\paragraph MSG_ext_icomms_Sender Sender function
+\paragraph MSG_ext_mw_master Master code
-A host can send an an asynchronous message with \c MSG_task_isend(). %As this function is non-blocking,
-we have to call \c MSG_comm_test() to know if the communication has finished and finally destroy it with a call to \c MSG_comm_destroy().
-It is also possible to call \c MSG_comm_wait() which, is provides a shortcut.
+This function has to be assigned to a #msg_process_t that will behave as the master. It should not be called directly
+but either given as a parameter to #MSG_process_create() or registered as a public function through
+#MSG_function_register() and then automatically assigned to a process through #MSG_launch_application().
- C style arguments (argc/argv) are interpreted as:
+C style arguments (argc/argv) are interpreted as:
- the number of tasks to distribute
- - the computation size of each task
- - the size of the files associated to each task
- - a list of host that will accept those tasks.
- - the time to sleep at the beginning of the function
- - This time defined the process sleep time
- if time = 0 use of MSG_comm_wait()
- if time > 0 use of MSG_comm_test()
-
-
-\until Receiver function
-
-\paragraph MSG_ext_icomms_Receiver Receiver function
-
-This function executes tasks when it receives them. %As the receiving is asynchronous we have to test the communication to know
-if it is completed or not with \c MSG_comm_test() or wait for the completion \c MSG_comm_wait().
-
- C style arguments (argc/argv) are interpreted as:
- - the id to use for received the communication.
- - the time to sleep at the beginning of the function
- - This time defined the process sleep time
- if time = 0 use of MSG_comm_wait()
- if time > 0 use of MSG_comm_test()
+ - the computational size of each task
+ - the communication size of each task
+ - the number of workers managed by the master.
-\until Test function
+Tasks are evenly sent in a round-robin style.
-\paragraph MSG_ext_icomms_core Simulation core
-
- This function is the core of the simulation and is divided only into 3 parts
- thanks to MSG_create_environment() and MSG_launch_application().
- -# Simulation settings : MSG_create_environment() creates a realistic
- environment
- -# Application deployment : create the processes on the right locations with
- MSG_launch_application()
- -# The simulation is run with #MSG_main()
-
- Its arguments are:
- - <i>platform_file</i>: the name of a file containing an valid surfxml platform description.
- - <i>application_file</i>: the name of a file containing a valid surfxml application description
+\until return 0;
+\until }
+\skipline Worker expects
-\until Main function
+\paragraph MSG_ext_mw_worker Worker code
-\paragraph MSG_ext_icomms_Main Main function
+This function has to be assigned to a #msg_process_t that has to behave as a worker. Just like the master function
+(described in \ref MSG_ext_mw_master), it should not be called directly.
-This initializes MSG, runs a simulation, and free all data-structures created by MSG.
+C style arguments (argc/argv) are interpreted as:
+ - a unique id used to build the mailbox name of the worker
-\until end_of_main
+This function keeps waiting for tasks and executes them as it receives them. When a special task named 'finalize' is
+received from the master, the process ends its execution.
-\dontinclude msg/icomms/peer2.c
+\until return 0;
+\until }
-\paragraph MSG_ext_icomms_fct_Waitall Waitall function for sender
+\paragraph MSG_ext_mw_core Main function
-The use of this function permit to send all messages and wait for the completion of all in one time.
+This function is the core of the simulation and is divided only into 3 parts:
+ -# Simulation settings : #MSG_create_environment() creates a realistic
+ environment
+ -# Application deployment : create the processes on the right locations with
+ #MSG_launch_application()
+ -# The simulation is run with #MSG_main()
-\skipline Sender function
-\until end_of_sender
+Its arguments are:
+ - <i>platform_file</i>: the name of a file containing an valid platform description.
+ - <i>deployment_file</i>: the name of a file containing a valid application description
+\line main
+\until OK;
+\until }
-\paragraph MSG_ext_icomms_fct_Waitany Waitany function
+\paragraph MSG_ext_mw_platform Example of a platform file
-The MSG_comm_waitany() function return the place of the first message send or receive from a xbt_dynar_t table.
+The following platform description can be found in \c examples/msg/platforms/small_platform.xml
+\include platforms/small_platform.xml
-\paragraph MSG_ext_icomms_fct_Waitany_sender From a sender
-We can use this function to wait all sent messages.
-\dontinclude msg/icomms/peer3.c
-\skipline Sender function
-\until end_of_sender
+\paragraph MSG_ext_mw_application Example of a deployment file
-\paragraph MSG_ext_icomms_fct_Waitany_receiver From a receiver
-We can also wait for the arrival of all messages.
-\dontinclude msg/icomms/peer3.c
-\skipline Receiver function
-\until end_of_receiver
+The following application description can be found in \c examples/msg/app-masterworker/app-masterworker_d.xml:
-\subsubsection MSG_ex_master_slave Basic Master/Slaves
+\include msg/app-masterworker/app-masterworker_d.xml
-Simulation of a master-slave application using a realistic platform
-and an external description of the deployment.
+\subsubsection MSG_ex_asynchronous_communications Asynchronous communications
-\paragraph MSG_ex_ms_TOC Table of contents:
+Simulation of asynchronous communications between a sender and a receiver using a realistic platform and
+an external description of the deployment.
- - \ref MSG_ext_ms_preliminary
- - \ref MSG_ext_ms_master
- - \ref MSG_ext_ms_slave
- - \ref MSG_ext_ms_forwarder
- - \ref MSG_ext_ms_core
- - \ref MSG_ext_ms_main
- - \ref MSG_ext_ms_helping
- - \ref MSG_ext_ms_application
- - \ref MSG_ext_ms_platform
+ - \ref MSG_ext_async_code
+ - \ref MSG_ext_async_preliminary
+ - \ref MSG_ext_async_Sender
+ - \ref MSG_ext_async_Receiver
+ - \ref MSG_ext_async_Main
+ - \ref MSG_ext_async_fct_Waitall
+ - \ref MSG_ext_async_fct_Waitany
<hr>
-\dontinclude msg/masterslave/masterslave_forwarder.c
+\dontinclude msg/async-wait/async-wait.c
+\paragraph MSG_ext_async_code Code of the application
-\paragraph MSG_ext_ms_preliminary Preliminary declarations
-
+\paragraph MSG_ext_async_preliminary Preliminary declarations
\skip include
-\until printf
-\until }
+\until Sender
-\paragraph MSG_ext_ms_master Master code
+\paragraph MSG_ext_async_Sender Sender function
-This function has to be assigned to a #msg_process_t that will behave as
-the master. It should not be called directly but either given as a
-parameter to #MSG_process_create() or registered as a public function
-through #MSG_function_register() and then automatically assigned to a
-process through #MSG_launch_application().
+A host can send an asynchronous message with \c MSG_task_isend(). As this function is non-blocking, we have to call
+\c MSG_comm_test() to know if the communication is complete and evenetually destroy it with a call to
+\c MSG_comm_destroy(). It is also possible to call \c MSG_comm_wait() which provides a shortcut.
-C style arguments (argc/argv) are interpreted as:
+ C style arguments (argc/argv) are interpreted as:
- the number of tasks to distribute
- the computation size of each task
- the size of the files associated to each task
- - a list of host that will accept those tasks.
-
-Tasks are dumbly sent in a round-robin style.
-
-\until end_of_master
-
-\paragraph MSG_ext_ms_slave Slave code
-
-This function has to be assigned to a #msg_process_t that has to behave
-as a slave. Just like the master function (described in \ref
-MSG_ext_ms_master), it should not be called directly.
-
-This function keeps waiting for tasks and executes them as it receives them.
-
-\until end_of_slave
-
-\paragraph MSG_ext_ms_forwarder Forwarder code
-
-This function has to be assigned to a #msg_process_t that has to behave
-as a forwarder. Just like the master function (described in \ref
-MSG_ext_ms_master), it should not be called directly.
+ - the number of receivers that will accept those tasks
+ - the time to sleep at the beginning of the function. This time defines the process sleep time:
+ - if time = 0, use MSG_comm_wait()
+ - if time > 0, use MSG_comm_test()
-C style arguments (argc/argv) are interpreted as a list of hosts that
-will accept those tasks.
+\until Receiver
-This function keeps waiting for tasks and dispatches them to its slaves.
+\paragraph MSG_ext_async_Receiver Receiver function
-\until end_of_forwarder
+This function executes tasks when it receives them. As the receiving is asynchronous, we have to test the completion of
+the communication with \c MSG_comm_test() or wait for it with \c MSG_comm_wait().
-\paragraph MSG_ext_ms_core Simulation core
+ C style arguments (argc/argv) are interpreted as:
+ - the id to use for received the communication.
+ - the time to sleep at the beginning of the function
+ - This time defined the process sleep time
+ - if time = 0 use of MSG_comm_wait()
+ - if time > 0 use of MSG_comm_test()
-This function is the core of the simulation and is divided only into 3 parts
-thanks to MSG_create_environment() and MSG_launch_application().
- -# Simulation settings : MSG_create_environment() creates a realistic
- environment
- -# Application deployment : create the processes on the right locations with
- MSG_launch_application()
- -# The simulation is run with #MSG_main()
+\until return
+\until }
-Its arguments are:
- - <i>platform_file</i>: the name of a file containing an valid surfxml platform description.
- - <i>application_file</i>: the name of a file containing a valid surfxml application description
+\paragraph MSG_ext_async_Main Main function
-\until end_of_test_all
+This function is the core of the simulation and is divided only into 3 parts:
+ -# Simulation settings : MSG_create_environment() loads a platform description
+ -# Application deployment : create the processes on the right locations with MSG_launch_application()
+ -# The simulation is run with #MSG_main()
-\paragraph MSG_ext_ms_main Main() function
+ Its arguments are:
+ - <i>platform_file</i>: the name of a file containing an valid platform description.
+ - <i>application_file</i>: the name of a file containing a valid application deployment.
-This initializes MSG, runs a simulation, and free all data-structures created by MSG.
+\until return
+\until }
-\until end_of_main
+\dontinclude msg/async-waitall/async-waitall.c
-\subsubsection MSG_ext_ms_helping Helping files
+\paragraph MSG_ext_async_fct_Waitall Waitall function
-\paragraph MSG_ext_ms_application Example of a deployment file
+The use of MSG_comm_waitall() allows a process to send all the tasks and then wait for the completion of all in one call.
-The following listing can be found in \c examples/msg/masterslave/deployment_masterslave_forwarder.xml:
+\skipline static
+\until return
+\until }
-\include msg/masterslave/deployment_masterslave_forwarder.xml
+\paragraph MSG_ext_async_fct_Waitany Waitany function
-\paragraph MSG_ext_ms_platform Example of a platform file
+The MSG_comm_waitany() function returns the place of the first message send or receive from a xbt_dynar.
-\include platforms/small_platform.xml
+\skipline static
+\until return
+\until }
*/