1 /*! \page faq Frequently Asked Questions
3 \htmlinclude .FAQ.doc.toc
5 \section faq_simgrid I'm new to SimGrid. I have some questions. Where should I start?
7 You are at the right place... Having a look to these
8 <a href="http://www.loria.fr/~quinson/articles/simgrid-tutorial.pdf">the tutorial slides</a>
9 (or to these <a href="http://graal.ens-lyon.fr/~alegrand/articles/slides_g5k_simul.pdf">old slides</a>,
11 <a href="http://graal.ens-lyon.fr/~alegrand/articles/Simgrid-Introduction.pdf">"obsolete" slides</a>)
12 may give you some insights on what SimGrid can help you to do and what
13 are its limitations. Then you definitely should read the \ref
14 MSG_examples. The \ref GRAS_tut can also help you.
16 If you are stuck at any point and if this FAQ cannot help you, please drop us a
17 mail to the user mailing list: <simgrid-user@lists.gforge.inria.fr>.
19 \subsection faq_interfaces What is the difference between MSG, SimDag, and GRAS? Do they serve the same purpose?
21 It depend on how you define "purpose", I guess ;)
23 They all allow you to build a prototype of application which you can run
24 within the simulator afterward. They all share the same simulation kernel,
25 which is the core of the SimGrid project. They differ by the way you express
28 With SimDag, you express your code as a collection of interdependent
29 parallel tasks. So, in this model, applications can be seen as a DAG of
30 tasks. This is the interface of choice for people wanting to port old
31 code designed for SimGrid v1 or v2 to the framework current version.
33 With both GRAS and MSG, your application is seen as a set of communicating
34 processes, exchanging data by the way of messages and performing computation
37 The difference between both is that MSG is somehow easier to use, but GRAS
38 is not limited to the simulator. Once you're done writing your GRAS code,
39 you can run your code both in the simulator or on a real platform. For this,
40 there is two implementations of the GRAS interface, one for simulation, one
41 for real execution. So, you just have to relink your code to chose one of
44 \subsection faq_generic First steps with SimGrid
46 If you decide to go for the MSG interface, please read carefully the
47 \ref MSG_examples. You'll find in \ref MSG_ex_master_slave a very
48 simple consisting of a master (that owns a bunch of tasks and
49 distributes them) , some slaves (that process tasks whenever they
50 receive one) and some forwarder agents (that simply pass the tasks
51 they receive to some slaves).
53 If you decide to go for the GRAS interface, you should definitively
54 read the \ref GRAS_tut. The first section constitutes an introduction
55 to the tool and presents the model we use. The second section
56 constitutes a complete step-by-step tutorial building a distributed
57 application from the beginning and exemplifying most of the GRAS
58 features in the process. The last section groups some HOWTOS
59 highlighting a given feature of the framework in a more concise way.
61 If you decide to go for another interface, I'm afraid your only sources
62 of information will be the source code and the mailing lists...
64 \subsection faq_visualization Visualizing and analyzing the results
66 It is sometime convenient to "see" how the agents are behaving. If you
67 like colors, you can use <tt>tools/MSG_visualization/colorize.pl </tt>
68 as a filter to your MSG outputs. It works directly with INFO. Beware,
69 INFO() prints on stderr. Do not forget to redirect if you want to
70 filter (e.g. with bash):
72 ./msg_test small_platform.xml small_deployment.xml 2>&1 | ../../tools/MSG_visualization/colorize.pl
75 We also have a more graphical output. Have a look at section \ref faq_tracing.
77 \subsection faq_C Argh! Do I really have to code in C?
79 Up until now, there is no binding for other languages. If you use C++,
80 you should be able to use the SimGrid library as a standard C library
81 and everything should work fine (simply <i>link</i> against this
82 library; recompiling SimGrid with a C++ compiler won't work and it
83 wouldn't help if you could).
85 In fact, we are currently working on Java bindings of MSG to allow
86 all the undergrad students of the world to use this tool. This is a
87 little more tricky than I would have expected, but the work is moving
88 fast forward [2006/05/13]. More languages are evaluated, but for now,
89 we do not feel a real demand for any other language. Please speak up!
91 \section faq_cmake Installing the SimGrid library with Cmake (since V3.4)
93 \subsection faq_intro Some generalitty
95 \subsubsection faq_intro1 What is Cmake?
97 CMake is a family of tools designed to build, test and package software. CMake is used to control the software compilation process using simple platform and compiler independent configuration files. CMake generates native makefiles and workspaces that can be used in the compiler environment of your choice. For more information see official web site <a href="http://www.cmake.org/">here</a>.
99 \subsubsection faq_intro2 Why cmake?
101 CMake permits to developers to compil projects on different plateforms. Then many tools are embedded like ctest for making test, a link to cdash for vizualise results but also test coverage and bug reports.
103 \subsubsection faq_intro3 What cmake need?
105 CMake needs some prerequists like :
107 \li c, c++ and java compiler regards to developers
108 \li ccmake for graphical used of CMake
109 \li cmake <a href="http://www.cmake.org/cmake/resources/software.html">(download page)</a>
111 \subsubsection faq_cmakeoption1 Liste of options
114 "cmake -D[name]=[value] ... ./"
116 [name] enable_gtnets [value] ON/OFF or TRUE/FALSE or 1/0
117 enable_java ON/OFF or TRUE/FALSE or 1/0
118 enable_lua ON/OFF or TRUE/FALSE or 1/0
119 enable_ruby ON/OFF or TRUE/FALSE or 1/0
120 enable_compile_optimizations ON/OFF or TRUE/FALSE or 1/0
121 enable_compile_warnings ON/OFF or TRUE/FALSE or 1/0
122 enable_smpi ON/OFF or TRUE/FALSE or 1/0
123 enable_maintainer_mode ON/OFF or TRUE/FALSE or 1/0
124 enable_supernovae ON/OFF or TRUE/FALSE or 1/0
125 enable_tracing ON/OFF or TRUE/FALSE or 1/0
126 enable_coverage ON/OFF or TRUE/FALSE or 1/0
127 enable_memcheck ON/OFF or TRUE/FALSE or 1/0
128 enable_model-checking ON/OFF or TRUE/FALSE or 1/0
129 enable_doc ON/OFF or TRUE/FALSE or 1/0
130 gtnets_path <path_to_gtnets_directory>
131 prefix <path_to_install_directory>
132 BIBTEX2HTML <path_to_bibtex2html>
133 with_context auto/ucontext/pthread/window
134 pipol_user <pipol_username>
137 \subsubsection faq_cmakeoption2 Options explaination
139 \li enable_gtnets : set to true implie that user wants to use gtnets.
141 \li enable_java : set to true implie that user wants to add java langage into simgrid compilation.
143 \li enable_lua : set to true implie that user wants to add lua langage into simgrid compilation.
145 \li enable_ruby : set to true implie that user wants to add ruby langage into simgrid compilation.
147 \li enable_compile_optimizations : add flags "-O3 -finline-functions -funroll-loops -fno-strict-aliasing"
149 \li enable_compile_warnings : add flags "-Wall -Wunused -Wmissing-prototypes -Wmissing-declarations -Wpointer-arith -Wchar-subscripts -Wcomment -Wformat -Wwrite-strings -Wno-unused-function -Wno-unused-parameter -Wno-strict-aliasing -Wno-format-nonliteral -Werror"
151 \li enable_smpi : Set to true if you want to use smpi lib. Actually on simgrid v3.4.1 Mac doesn't support lib smpi.
153 \li enable_maintainer_mode : set to true it remakes some files.
155 \li enable_supernovae : set to true make one file for each lib and compile with those generated files.
157 \li enable_tracing : To enable the generation of simulation traces for visualization
159 \li enable_coverage : When set to true this option enable code coverage by setting -fprofile-arcs -ftest-coverage flags.
161 \li enable_memcheck : When set to true this option enable tests for memcheck.
163 \li enable_model-checking : Enable the model checking when set to true.
165 \li enable_doc : Generate the documentation for simgrid with make command. (You can also make the doc manually with command : make html)
167 \li gtnets_path : Path to gtnets install directory (ex /usr)
169 \li prefix : Path where are installed lib/ doc/ and include/ directories (ex /usr/local)
171 \li BIBTEX2HTML : Path where is installed bibtex2html.
173 \li with context : specify which context the user wants to use.
175 \li pipol_user : specify your pipol username if you want to use the pipol-remote command.
177 \subsubsection faq_cmakeoption3 Initialisation
179 Those options are initialized the first time you launch "cmake ." whithout specified option.
186 enable_compile_optimizations off
187 enable_compile_warnings off
189 enable_maintainer_mode off
190 enable_supernovae off
194 enable_model-checking off
204 \subsubsection faq_cmakeoption4 Option's cache and how to reset?
206 When options have been set they are keep into a cache file named "CMakeCache.txt". So if you want
207 reset values you just delete this file located to the project directory.
209 \subsection faq_cmakecompilation Cmake compilation
211 \subsubsection faq_cmakecompilation1 With command line.
214 cmake -D[name]=[value] ... ./
218 \subsubsection faq_cmakecompilation2 With ccmake tool.
223 Then follow instructions.
225 \subsubsection faq_cmakecompilation2bis Build out of source.
227 As cmake generate many files used for compilation, we recommand to make a build directory.
228 For examples you can make :
231 "navarrop@caraja:~/Developments$ cd simgrid/"
232 "navarrop@caraja:~/Developments/simgrid$ mkdir build_directory"
233 "navarrop@caraja:~/Developments/simgrid$ cd build_directory/"
234 "navarrop@caraja:~/Developments/simgrid/build_directory$ cmake ../"
235 "navarrop@caraja:~/Developments/simgrid/build_directory$ make"
238 Or complety out of sources :
241 "navarrop@caraja:~/Developments$ mkdir build_dir"
242 "navarrop@caraja:~/Developments$ cd build_dir/"
243 "navarrop@caraja:~/Developments/build_dir$ cmake ../simgrid/"
244 "navarrop@caraja:~/Developments/build_dir$ make"
247 Those two kind of compilation permit to delete files created by compilation easier.
249 \subsubsection faq_cmakecompilation3 Resume of command line
253 cmake <path> configure the project
254 make build all targets
255 make VERBOSE=1 build all targets and print build command lines
256 make check test all targets and summarize
257 make dist make the distrib
258 make distcheck check the dist (make + make dist + make check)
259 make install install the project (doc/ lib/ include/)
260 make uninstall uninstall the project (doc/ lib/ include/)
261 make clean clean all targets
262 make java-clean clean files created by java option
263 make doc-clean clean files created for making doc
264 make supernovae-clean clean supernovae files
265 make maintainer-clean clean maintainer files
266 make all-clean execute the 5 upper clean command
267 make html Create simgrid documentation
270 When the project have been succesfully compiling and build you can make tests.
274 ctest launch only tests
276 ctest -D Continuous(Start|Update|Configure|Build)
277 ctest -D Continuous(Test|Coverage|MemCheck|Submit)
278 ctest -D Experimental
279 ctest -D Experimental(Start|Update|Configure|Build)
280 ctest -D Experimental(Test|Coverage|MemCheck|Submit)
282 ctest -D Nightly(Start|Update|Configure|Build)
283 ctest -D Nightly(Test|Coverage|MemCheck|Submit)
284 ctest -D NightlyMemoryCheck
287 If you want to test before make a commit you can simply make "ctest -D Experimental" and then you can visualize results submitted into Cdash. <a href="http://cdash.inria.fr/CDash/index.php?project=Simgrid">(Go to Cdash site)</a>.
289 \subsubsection faq_cmakecompilation5 Examples for different mode.
293 cmake -Denable_maintainer_mode=on ./
295 -- lookign for config.h
296 with_context auto change to ucontext
297 GIT_DATE : 2010-05-04~09-59-15
298 GIT_VERSION : 53ec816
299 GIT_SVN_VERSION : 7669
301 Configuration of package `simgrid' (revision 7669) on arch (=4):
303 SITE : Linux_2.6.31-21-generic_x86_64
304 Release : simgrid-3.4~rev7669
306 Compiler: c++ : /usr/bin/c++
307 version: c++ (Ubuntu 4.4.1-4ubuntu9) 4.4.1
308 Compiler: c : /usr/bin/gcc
309 version: gcc (Ubuntu 4.4.1-4ubuntu9) 4.4.1
311 CFlags : -I/usr/lib/ruby/1.8/x86_64-linux -I/usr/include/lua5.1 -g3
313 LDFlags : -L/usr/lib/
315 Context backend: ucontext
327 Simgrid dependencies: -lm -lruby1.8 -module -ldl -llua5.1 -lrt
328 Gras dependencies : -lm -lpthread -lrt
331 INSTALL_PREFIX: /usr/local
335 -- Build files have been written to: /home/navarrop/Developments/simgrid
340 cmake -Dsupernovae=on ./
342 -- lookign for config.h
343 with_context auto change to ucontext
344 GIT_DATE : 2010-05-04~09-59-15
345 GIT_VERSION : 53ec816
346 GIT_SVN_VERSION : 7669
348 Configuration of package `simgrid' (revision 7669) on arch (=4):
349 BUILDNAME : SUPERNOVAE
350 SITE : Linux_2.6.31-21-generic_x86_64
351 Release : simgrid-3.4~rev7669
353 Compiler: c++ : /usr/bin/c++
354 version: c++ (Ubuntu 4.4.1-4ubuntu9) 4.4.1
355 Compiler: c : /usr/bin/gcc
356 version: gcc (Ubuntu 4.4.1-4ubuntu9) 4.4.1
358 CFlags : -O3 -finline-functions -funroll-loops -fno-strict-aliasing -Wall -Wunused -Wmissing-prototypes -Wmissing-declarations -Wpointer-arith -Wchar-subscripts -Wcomment -Wformat -Wwrite-strings -Wno-unused-function -Wno-unused-parameter -Wno-strict-aliasing -Wno-format-nonliteral -Werror -I/usr/lib/ruby/1.8/x86_64-linux -I/usr/include/lua5.1 -g3
360 LDFlags : -L/usr/lib/
362 Context backend: ucontext
374 Simgrid dependencies: -lm -lruby1.8 -module -ldl -llua5.1 -lrt
375 Gras dependencies : -lm -lpthread -lrt
378 INSTALL_PREFIX: /usr/local
382 -- Build files have been written to: /home/navarrop/Developments/simgrid
388 cmake -Dgtnets_path=/home/navarrop/Bureau/usr/ ./
390 -- lookign for config.h
391 with_context auto change to ucontext
392 GIT_DATE : 2010-05-04~09-59-15
393 GIT_VERSION : 53ec816
394 GIT_SVN_VERSION : 7669
396 Configuration of package `simgrid' (revision 7669) on arch (=4):
398 SITE : Linux_2.6.31-21-generic_x86_64
399 Release : simgrid-3.4~rev7669
401 Compiler: c++ : /usr/bin/c++
402 version: c++ (Ubuntu 4.4.1-4ubuntu9) 4.4.1
403 Compiler: c : /usr/bin/gcc
404 version: gcc (Ubuntu 4.4.1-4ubuntu9) 4.4.1
406 CFlags : -O3 -finline-functions -funroll-loops -fno-strict-aliasing -Wall -Wunused -Wmissing-prototypes -Wmissing-declarations -Wpointer-arith -Wchar-subscripts -Wcomment -Wformat -Wwrite-strings -Wno-unused-function -Wno-unused-parameter -Wno-strict-aliasing -Wno-format-nonliteral -Werror -I/usr/lib/ruby/1.8/x86_64-linux -L/usr/lib -I/usr/include/gtnets -I/usr/include/lua5.1 -g3
407 CPPFlags: -L/usr/lib -I/usr/include/gtnets
408 LDFlags : -L/usr/lib/
410 Context backend: ucontext
422 Simgrid dependencies: -lm -lruby1.8 -module -ldl -llua5.1 -lgtnets -lrt
423 Gras dependencies : -lm -lpthread -lrt
426 INSTALL_PREFIX: /usr/local
430 -- Build files have been written to: /home/navarrop/Developments/simgrid
434 \subsection faq_cmakeinstall How to install with cmake?
436 \subsubsection faq_cmakeinstall1 From svn.
439 cmake -Denable_maintainer_mode=on -Dprefix=/home/navarrop/Bureau/install_simgrid ./
444 \subsubsection faq_cmakeinstall2 From a distrib
447 For version 3.4.1 and 3.4
448 cmake -Dprefix=/home/navarrop/Bureau/install_simgrid ./
452 cmake -Dprefix=/home/navarrop/Bureau/install_simgrid ./
457 \subsection faq_cmakehowto How to modified sources files for developers
459 \subsubsection faq_cmakehowto1 Add an executable or examples.
461 If you want make an executable you have to create a CMakeList.txt to the src directory.
462 You must specified where to create the executable, source list, dependencies and the name of the binary.
465 cmake_minimum_required(VERSION 2.6)
467 set(EXECUTABLE_OUTPUT_PATH "./")
468 set(LIBRARY_OUTPUT_PATH "${PROJECT_DIRECTORY}/lib")
470 add_executable(get_sender get_sender.c) #add_executable(<name_of_target> <src list>)
472 ### Add definitions for compile
473 target_link_libraries(get_sender simgrid m pthread -fprofile-arcs) #target_link_libraries(<name_of_targe> <dependencies>)
476 Then you have to modified <project/directory>/buildtools/Cmake/MakeExeLib.cmake and add
479 add_subdirectory(${PROJECT_DIRECTORY}/<path_where_is_CMakeList.txt>)
482 \subsubsection faq_cmakehowto2 Delete/add sources to lib.
484 If you want modified, add or delete source files from a library you have to edit <project/directory>/buildtools/Cmake/DefinePackages.cmake
488 ${PROJECT_DIRECTORY}/src/java/simgrid/msg/MsgException.java
489 ${PROJECT_DIRECTORY}/src/java/simgrid/msg/JniException.java
490 ${PROJECT_DIRECTORY}/src/java/simgrid/msg/NativeException.java
491 ${PROJECT_DIRECTORY}/src/java/simgrid/msg/HostNotFoundException.java
492 ${PROJECT_DIRECTORY}/src/java/simgrid/msg/ProcessNotFoundException.java
493 ${PROJECT_DIRECTORY}/src/java/simgrid/msg/Msg.java
494 ${PROJECT_DIRECTORY}/src/java/simgrid/msg/Process.java
495 ${PROJECT_DIRECTORY}/src/java/simgrid/msg/Host.java
496 ${PROJECT_DIRECTORY}/src/java/simgrid/msg/Task.java
497 ${PROJECT_DIRECTORY}/src/java/simgrid/msg/MsgNative.java
498 ${PROJECT_DIRECTORY}/src/java/simgrid/msg/ApplicationHandler.java
499 ${PROJECT_DIRECTORY}/src/java/simgrid/msg/Sem.java
503 \subsubsection faq_cmakehowto3 Add test
505 If you want modified, add or delete tests you have to edit <project/directory>/buildtools/Cmake/AddTests.cmake
506 with this function : ADD_TEST(<name> <bin> <ARGS>)
509 add_test(test-simdag-1 ${PROJECT_DIRECTORY}/testsuite/simdag/sd_test --cfg=path:${PROJECT_DIRECTORY}/testsuite/simdag small_platform_variable.xml)
512 \subsection faq_PIPOL Pipol-remote
514 Now we offer the possibility to test your local sources on pipol platforms before a commit. Of course you have to be user of pipol <a href="https://pipol.inria.fr/users/">(Account request)</a> cause you need to give your pipol_username to cmake. Here is a list of available systems :
516 amd64_kvm-linux-debian-lenny
517 amd64_kvm-linux-debian-testing
519 amd64-linux-centos-5.dd.gz
520 amd64-linux-debian-etch.dd.gz
521 amd64-linux-debian-lenny.dd.gz
522 amd64-linux-debian-testing.dd.gz
523 amd64-linux-fedora-core10.dd.gz
524 amd64-linux-fedora-core11.dd.gz
525 amd64-linux-fedora-core12.dd.gz
526 amd64-linux-fedora-core13.dd.gz
527 amd64-linux-fedora-core7.dd.gz
528 amd64-linux-fedora-core8.dd.gz
529 amd64-linux-fedora-core9.dd.gz
530 amd64-linux-mandriva-2007_springs_powerpack.dd.gz
531 amd64-linux-mandriva-2009_powerpack.dd.gz
532 amd64-linux-opensuse-11.dd.gz
533 amd64-linux-redhatEL-5.0.dd.gz
534 amd64-linux-suse-LES10.dd.gz
535 amd64-linux-ubuntu-feisty.dd.gz
536 amd64-linux-ubuntu-hardy.dd.gz
537 amd64-linux-ubuntu-intrepid.dd.gz
538 amd64-linux-ubuntu-jaunty.dd.gz
539 amd64-linux-ubuntu-karmic.dd.gz
540 amd64-linux-ubuntu-lucid.dd.gz
541 amd64-unix-freebsd-7.dd.gz
542 amd64-windows-server-2003-64bits.dd.gz
543 amd64-windows-server-2008-64bits.dd.gz
544 i386_kvm-linux-debian-lenny
545 i386_kvm-linux-debian-testing
546 i386_kvm-linux-fedora-core13
547 i386_kvm-windows-xp-pro-sp3
548 i386-linux-centos-5.dd.gz
549 i386-linux-debian-etch.dd.gz
550 i386-linux-debian-lenny.dd.gz
551 i386-linux-debian-testing.dd.gz
552 i386-linux-fedora-core10.dd.gz
553 i386-linux-fedora-core11.dd.gz
554 i386-linux-fedora-core12.dd.gz
555 i386-linux-fedora-core13.dd.gz
556 i386-linux-fedora-core7.dd.gz
557 i386-linux-fedora-core8.dd.gz
558 i386-linux-fedora-core9.dd.gz
559 i386-linux-mandriva-2007_springs_powerpack.dd.gz
560 i386-linux-mandriva-2009_powerpack.dd.gz
561 i386-linux-opensuse-11.dd.gz
562 i386-linux-redhatEL-5.0.dd.gz
563 i386-linux-suse-LES10.dd.gz
564 i386-linux-ubuntu-feisty.dd.gz
565 i386-linux-ubuntu-hardy.dd.gz
566 i386-linux-ubuntu-intrepid.dd.gz
567 i386-linux-ubuntu-jaunty.dd.gz
568 i386-linux-ubuntu-karmic.dd.gz
569 i386-linux-ubuntu-lucid.dd.gz
570 i386_mac-mac-osx-server-leopard.dd.gz
571 i386-unix-freebsd-7.dd.gz
572 i386-unix-opensolaris-10.dd.gz
573 i386-unix-opensolaris-11.dd.gz
574 i386-unix-solaris-10.dd.gz
575 ia64-linux-debian-lenny.dd
576 ia64-linux-fedora-core9.dd
577 ia64-linux-redhatEL-5.0.dd
578 x86_64_mac-mac-osx-server-snow-leopard.dd.gz
579 x86_mac-mac-osx-server-snow-leopard.dd.gz
582 Two kind of uses are possible :
584 This command copy your source and execute a configure then a build and finish with tests.
585 bob@caraja:~/Developments/simgrid/tmp_build$ make <name_of_image>
587 This command copy your source and execute a \"ctest -D Experimental\" and submit the result to cdash.
588 bob@caraja:~/Developments/simgrid/tmp_build$ make <name_of_image>_experimental
590 All commands are resumed with :
592 bob@caraja:~/Developments/simgrid/tmp_build$ make pipol_experimental_list_images
593 bob@caraja:~/Developments/simgrid/tmp_build$ make pipol_test_list_images
596 \subsection faq_cmakeExplain Explaination of sources files for cmake
600 Those files are the "main parts". One located at the project directory call all the cmake sources files. The others
601 are little projects called by the first for make examples.
603 \li CompleteInFiles.cmake
605 Complete all .in files and define Variables for h files
607 \li GenerateDoc.cmake
609 This file make the html documentation.
613 Here are callled all "CMakeLists.txt" for make executables and libraries.
617 This file is called at the end of the build for summarize environment variables.
619 \li DefinePackages.cmake
621 Here is defined sources packages for compiling libs.
625 Defined flags which are used for compiling sources.
629 Here are made files for the supernovae mode.
633 Here is defined packages for install simgrid and make a distribution.
635 \li MaintainerMode.cmake
637 Part where are generated source files for maintainer mode.
641 Here are defined options and initialized values.
645 All tests are listed.
647 \li CTestConfig.cmake
649 Properties which link tests with dashboard.
651 \subsection faq_cmakeList List of files added for cmake
653 Here is a list of files involved into cmake build (relative to project directory path) :
658 ./buildtools/Cmake/AddTests.cmake
659 ./buildtools/Cmake/CompleteInFiles.cmake
660 ./buildtools/Cmake/CTestConfig.cmake
661 ./buildtools/Cmake/DefinePackages.cmake
662 ./buildtools/Cmake/Distrib.cmake
663 ./buildtools/Cmake/Flags.cmake
664 ./buildtools/Cmake/GenerateDocs.cmake
665 ./buildtools/Cmake/MaintainerMode.cmake
666 ./buildtools/Cmake/MakeExeLib.cmake
667 ./buildtools/Cmake/MakeExeLibWin.cmake
668 ./buildtools/Cmake/MakeJava.cmake
669 ./buildtools/Cmake/Option.cmake
670 ./buildtools/Cmake/PrintArgs.cmake
671 ./buildtools/Cmake/Supernovae.cmake
673 CMakeLists for each binaries or examples:
676 ./teshsuite/gras/empty_main/CMakeLists.txt
677 ./teshsuite/gras/small_sleep/CMakeLists.txt
678 ./teshsuite/gras/datadesc/CMakeLists.txt
679 ./teshsuite/gras/msg_handle/CMakeLists.txt
680 ./teshsuite/simdag/CMakeLists.txt
681 ./teshsuite/simdag/partask/CMakeLists.txt
682 ./teshsuite/simdag/platforms/CMakeLists.txt
683 ./teshsuite/simdag/network/CMakeLists.txt
684 ./teshsuite/simdag/network/mxn/CMakeLists.txt
685 ./teshsuite/simdag/network/p2p/CMakeLists.txt
686 ./teshsuite/xbt/CMakeLists.txt
687 ./teshsuite/msg/CMakeLists.txt
688 ./tools/gras/CMakeLists.txt
689 ./tools/tesh/CMakeLists.txt
690 ./testsuite/simdag/CMakeLists.txt
691 ./testsuite/xbt/CMakeLists.txt
692 ./testsuite/surf/CMakeLists.txt
693 ./examples/gras/properties/CMakeLists.txt
694 ./examples/gras/ping/CMakeLists.txt
695 ./examples/gras/pmm/CMakeLists.txt
696 ./examples/gras/mmrpc/CMakeLists.txt
697 ./examples/gras/synchro/CMakeLists.txt
698 ./examples/gras/timer/CMakeLists.txt
699 ./examples/gras/mutual_exclusion/simple_token/CMakeLists.txt
700 ./examples/gras/spawn/CMakeLists.txt
701 ./examples/gras/chrono/CMakeLists.txt
702 ./examples/gras/rpc/CMakeLists.txt
703 ./examples/gras/all2all/CMakeLists.txt
704 ./examples/simdag/properties/CMakeLists.txt
705 ./examples/simdag/CMakeLists.txt
706 ./examples/simdag/metaxml/CMakeLists.txt
707 ./examples/simdag/dax/CMakeLists.txt
708 ./examples/smpi/CMakeLists.txt
709 ./examples/amok/bandwidth/CMakeLists.txt
710 ./examples/amok/saturate/CMakeLists.txt
711 ./examples/msg/priority/CMakeLists.txt
712 ./examples/msg/properties/CMakeLists.txt
713 ./examples/msg/migration/CMakeLists.txt
714 ./examples/msg/gtnets/CMakeLists.txt
715 ./examples/msg/parallel_task/CMakeLists.txt
716 ./examples/msg/trace/CMakeLists.txt
717 ./examples/msg/suspend/CMakeLists.txt
718 ./examples/msg/masterslave/CMakeLists.txt
719 ./examples/msg/actions/CMakeLists.txt
720 ./examples/msg/sendrecv/CMakeLists.txt
723 \section faq_installation Installing the SimGrid library with Autotools (valid until V3.3.4)
725 Many people have been asking me questions on how to use SimGrid. Quite
726 often, the questions were not really about SimGrid but on the
727 installation process. This section is intended to help people that are
728 not familiar with compiling C files under UNIX. If you follow these
729 instructions and still have some troubles, drop an e-mail to
730 <simgrid-user@lists.gforge.inria.fr>.
732 \subsection faq_compiling Compiling SimGrid from a stable archive
734 First of all, you need to download the latest version of SimGrid from
735 <a href="http://gforge.inria.fr/frs/?group_id=12">here</a>.
736 Suppose you have uncompressed SimGrid in some temporary location of
737 your home directory (say <tt>/home/joe/tmp/simgrid-3.0.1 </tt>). The
738 simplest way to use SimGrid is to install it in your home
739 directory. Change your directory to
740 <tt>/home/joe/tmp/simgrid-3.0.1</tt> and type
743 ./configure --prefix=$HOME
748 If at some point, something fails, check the section \ref faq_trouble_compil .
749 If it does not help, you can report this problem to the
750 list but, please, avoid sending a laconic mail like "There is a problem. Is it
751 okay?". Send the config.log file which is automatically generated by
752 configure. Try to capture both the standard output and the error output of the
753 <tt>make</tt> command with <tt>script</tt>. There is no way for us to help you
754 without the relevant bits of information.
756 Now, the following directory should have been created :
758 \li <tt>/home/joe/doc/simgrid/html/</tt>
759 \li <tt>/home/joe/lib/</tt>
760 \li <tt>/home/joe/include/</tt>
762 SimGrid is not a binary, it is a library. Both a static and a dynamic
763 version are available. Here is what you can find if you try a <tt>ls
766 \verbatim libsimgrid.a libsimgrid.la libsimgrid.so libsimgrid.so.0 libsimgrid.so.0.0.1
769 Thus, there is two ways to link your program with SimGrid:
770 \li Either you use the static version, e.g
771 \verbatim gcc libsimgrid.a -o MainProgram MainProgram.c
773 In this case, all the SimGrid functions are directly
774 included in <tt>MainProgram</tt> (hence a bigger binary).
775 \li Either you use the dynamic version (the preferred method)
776 \verbatim gcc -lsimgrid -o MainProgram MainProgram.c
778 In this case, the SimGrid functions are not included in
779 <tt>MainProgram</tt> and you need to set your environment
780 variable in such a way that <tt>libsimgrid.so</tt> will be
781 found at runtime. This can be done by adding the following
782 line in your .bashrc (if you use bash and if you have
783 installed the SimGrid libraries in your home directory):
784 \verbatim export LD_LIBRARY_PATH=$HOME/lib/:$LD_LIBRARY_PATH
787 \subsection faq_compiling_java Java bindings don't get compiled
789 The configure script detects automatically whether you have the
790 softwares needed to use the Java bindings or not. At the end of the
791 configure, you can see the configuration picked by the script, which
792 should look similar to
793 \verbatim Configuration of package simgrid' (version 3.3.4-svn) on
796 Compiler: gcc (version: )
798 CFlags: -O3 -finline-functions -funroll-loops -fno-strict-aliasing -Wall -Wunused -Wmissing-prototypes -Wmissing-declarations -Wpointer-arith -Wchar-subscripts -Wcomment -Wformat -Wwrite-strings -Wno-unused-function -Wno-unused-parameter -Wno-strict-aliasing -Wno-format-nonliteral -Werror -g3
802 Context backend: ucontext
809 In this example, Java backends won't be compiled.
811 On Debian-like systems (which includes ubuntu), you need the following
812 packages: sun-java6-jdk libgcj10-dev. If you cannot find the
813 libgcj10-dev, try another version, like libgcj9-dev (on Ubuntu before
814 9.10) or libgcj11-dev (not released yet, but certainly one day).
815 Please note that you need to activate the contrib and non-free
816 repositories in Debian, and the universe ones in Ubuntu. Java comes at
819 \subsection faq_compiling_snapshoot SimGrid development snapshots
821 We have very high standards on software quality, and we are reluctant releasing
822 a stable release as long as there is still some known bug in the code base. In
823 addition, we added quite an extensive test base, making sure that we correctly
824 test the most important parts of the tool.
826 As an unfortunate conclusion, there may be some time between the stable
827 releases. If you want to benefit from the most recent features we introduced,
828 but don't want to take the risk of an untested version from the SVN, then
829 development snapshots are done for you.
831 These are pre-releases of SimGrid that still fail some tests about features
832 that almost nobody use, or on platforms not being in our core target (which is
833 Linux, Mac, other Unixes and Windows, from the most important to the less
834 one). That means that using this development releases should be safe for most
837 These archives can be found on
838 <a href="http://www.loria.fr/~quinson/simgrid.html">this web page</a>. Once you
839 got the lastest archive, you can compile it just like any archive (see above).
841 \subsection faq_compiling_svn Compiling SimGrid from the SVN
843 The project development takes place in the SVN, where all changes are
844 committed when they happen. Then every once in a while, we make sure that the
845 code quality meets our standard and release an archive from the code in the
846 SVN. We afterward go back to the development in the SVN. So, if you need a
847 recently added feature and can afford some little problem with the stability
848 of the lastest features, you may want to use the SVN version instead of a
851 For that, you first need to get the "simgrid" module from
852 <a href="http://gforge.inria.fr/scm/?group_id=12">here</a>.
854 You won't find any <tt>configure</tt> and a few other things
855 (<tt>Makefile.in</tt>'s, documentation, ...) will be missing as well. The
856 reason for that is that all these files have to be regenerated using the
857 latest versions of <tt>autoconf</tt>, <tt>libtool</tt>, <tt>automake</tt>
858 (>1.9) and <tt>doxygen</tt> (>1.4). To generate the <tt>configure</tt> and
859 the <tt>Makefile.in</tt>'s, you just have to launch the <tt>bootstrap</tt>
860 command that resides in the top of the source tree. Then just follow the
861 instructions of Section \ref faq_compiling.
863 We insist on the fact that you really need the latest versions of
864 autoconf, automake and libtool. Doing this step on exotic architectures/systems
865 (i.e. anything different from a recent linux distribution) may be
866 ... uncertain. If you need to compile the SVN version on a machine where all these
867 dependencies are not met, the easiest is to do <tt>make dist</tt> in the SVN
868 directory of another machine where all dependencies are met. It will create an
869 archive you may deploy on other sites just as a regular stable release.
871 In summary, the following commands will checkout the SVN, regenerate the
872 configure script and friends, configure SimGrid and build it.
874 \verbatim svn checkout svn://scm.gforge.inria.fr/svn/simgrid/simgrid/trunk simgrid
877 ./configure --enable-maintainer-mode --prefix=<where to install SimGrid>
880 Then, if you want to install SimGrid on the current box, just do:
881 \verbatim make install \endverbatim
883 If you want to build an snapshot of the SVN to deploy it on another box (for
884 example because the other machine don't have the autotools), do:
885 \verbatim make dist \endverbatim
887 Moreover, you should never call the autotools manually since you must run
888 them in a specific order with specific arguments. Most of the times, the
889 makefiles will automatically call the tools for you. When it's not possible
890 (such as the first time you checkout the SVN), use the ./bootstrap command
891 to call them explicitly.
894 \subsection faq_setting_MSG Setting up your own MSG code
896 Do not build your simulator by modifying the SimGrid examples. Go
897 outside the SimGrid source tree and create your own working directory
898 (say <tt>/home/joe/SimGrid/MyFirstScheduler/</tt>).
900 Suppose your simulation has the following structure (remember it is
901 just an example to illustrate a possible way to compile everything;
902 feel free to organize it as you want).
904 \li <tt>sched.h</tt>: a description of the core of the
905 scheduler (i.e. which functions are can be used by the
906 agents). For example we could find the following functions
907 (master, forwarder, slave).
909 \li <tt>sched.c</tt>: a C file including <tt>sched.h</tt> and
910 implementing the core of the scheduler. Most of these
911 functions use the MSG functions defined in section \ref
914 \li <tt>masterslave.c</tt>: a C file with the main function, i.e.
915 the MSG initialization (MSG_global_init()), the platform
916 creation (e.g. with MSG_create_environment()), the
917 deployment phase (e.g. with MSG_function_register() and
918 MSG_launch_application()) and the call to
921 To compile such a program, we suggest to use the following
922 Makefile. It is a generic Makefile that we have used many times with
923 our students when we teach the C language.
927 masterslave: masterslave.o sched.o
929 INSTALL_PATH = $$HOME
931 PEDANTIC_PARANOID_FREAK = -O0 -Wshadow -Wcast-align \
932 -Waggregate-return -Wmissing-prototypes -Wmissing-declarations \
933 -Wstrict-prototypes -Wmissing-prototypes -Wmissing-declarations \
934 -Wmissing-noreturn -Wredundant-decls -Wnested-externs \
935 -Wpointer-arith -Wwrite-strings -finline-functions
936 REASONABLY_CAREFUL_DUDE = -Wall
937 NO_PRAYER_FOR_THE_WICKED = -w -O2
938 WARNINGS = $(REASONABLY_CAREFUL_DUDE)
939 CFLAGS = -g $(WARNINGS)
941 INCLUDES = -I$(INSTALL_PATH)/include
942 DEFS = -L$(INSTALL_PATH)/lib/
943 LDADD = -lm -lsimgrid
947 $(CC) $(INCLUDES) $(DEFS) $(CFLAGS) $^ $(LIBS) $(LDADD) -o $@
950 $(CC) $(INCLUDES) $(DEFS) $(CFLAGS) -c -o $@ $<
953 rm -f $(BIN_FILES) *.o *~
959 The first two lines indicates what should be build when typing make
960 (<tt>masterslave</tt>) and of which files it is to be made of
961 (<tt>masterslave.o</tt> and <tt>sched.o</tt>). This makefile assumes
962 that you have set up correctly your <tt>LD_LIBRARY_PATH</tt> variable
963 (look, there is a <tt>LDADD = -lm -lsimgrid</tt>). If you prefer using
964 the static version, remove the <tt>-lsimgrid</tt> and add a
965 <tt>$(INSTALL_PATH)/lib/libsimgrid.a</tt> on the next line, right
966 after the <tt>LIBS = </tt>.
968 More generally, if you have never written a Makefile by yourself, type
969 in a terminal : <tt>info make</tt> and read the introduction. The
970 previous example should be enough for a first try but you may want to
971 perform some more complex compilations...
973 \subsection faq_setting_GRAS Setting up your own GRAS code
975 If you use the GRAS interface instead of the MSG one, then previous section
976 is not the better source of information. Instead, you should check the GRAS
977 tutorial in general, and the \ref GRAS_tut_tour_setup in particular.
979 \section faq_howto Feature related questions
981 \subsection faq_MIA "Could you please add (your favorite feature here) to SimGrid?"
983 Here is the deal. The whole SimGrid project (MSG, SURF, GRAS, ...) is
984 meant to be kept as simple and generic as possible. We cannot add
985 functions for everybody's needs when these functions can easily be
986 built from the ones already in the API. Most of the time, it is
987 possible and when it was not possible we always have upgraded the API
988 accordingly. When somebody asks us a question like "How to do that?
989 Is there a function in the API to simply do this?", we're always glad
990 to answer and help. However if we don't need this code for our own
991 need, there is no chance we're going to write it... it's your job! :)
992 The counterpart to our answers is that once you come up with a neat
993 implementation of this feature (task duplication, RPC, thread
994 synchronization, ...), you should send it to us and we will be glad to
995 add it to the distribution. Thus, other people will take advantage of
996 it (and we don't have to answer this question again and again ;).
998 You'll find in this section a few "Missing In Action" features. Many
999 people have asked about it and we have given hints on how to simply do
1000 it with MSG. Feel free to contribute...
1002 \subsection faq_MIA_MSG MSG features
1004 \subsubsection faq_MIA_examples I want some more complex MSG examples!
1006 Many people have come to ask me a more complex example and each time,
1007 they have realized afterward that the basics were in the previous three
1010 Of course they have often been needing more complex functions like
1011 MSG_process_suspend(), MSG_process_resume() and
1012 MSG_process_isSuspended() (to perform synchronization), or
1013 MSG_task_Iprobe() and MSG_process_sleep() (to avoid blocking
1014 receptions), or even MSG_process_create() (to design asynchronous
1015 communications or computations). But the examples are sufficient to
1018 We know. We should add some more examples, but not really some more
1019 complex ones... We should add some examples that illustrate some other
1020 functionalists (like how to simply encode asynchronous
1021 communications, RPC, process migrations, thread synchronization, ...)
1022 and we will do it when we will have a little bit more time. We have
1023 tried to document the examples so that they are understandable. Tell
1024 us if something is not clear and once again feel free to participate!
1027 \subsubsection faq_MIA_taskdup Missing in action: MSG Task duplication/replication
1029 There is no task duplication in MSG. When you create a task, you can
1030 process it or send it somewhere else. As soon as a process has sent
1031 this task, he doesn't have this task anymore. It's gone. The receiver
1032 process has got the task. However, you could decide upon receiving to
1033 create a "copy" of a task but you have to handle by yourself the
1034 semantic associated to this "duplication".
1036 As we already told, we prefer keeping the API as simple as
1037 possible. This kind of feature is rather easy to implement by users
1038 and the semantic you associate really depends on people. Having a
1039 *generic* task duplication mechanism is not that trivial (in
1040 particular because of the data field). That is why I would recommand
1041 that you write it by yourself even if I can give you advice on how to
1044 You have the following functions to get informations about a task:
1045 MSG_task_get_name(), MSG_task_get_compute_duration(),
1046 MSG_task_get_remaining_computation(), MSG_task_get_data_size(),
1047 and MSG_task_get_data().
1049 You could use a dictionary (#xbt_dict_t) of dynars (#xbt_dynar_t). If
1050 you still don't see how to do it, please come back to us...
1052 \subsubsection faq_MIA_asynchronous I want to do asynchronous communications in MSG
1054 In the past (version <= 3.4), there was no function to perform asynchronous communications.
1055 It could easily be implemented by creating new process when needed though. Since version 3.5,
1056 we have introduced the following functions:
1061 - MSG_comm_waitall()
1062 - MSG_comm_waitany()
1063 - MSG_comm_destroy()
1065 We refer you to the description of these functions for more details on their usage as well
1066 as to the exemple section on \ref MSG_ex_asynchronous_communications.
1068 \subsubsection faq_MIA_thread_synchronization I need to synchronize my MSG processes
1070 You obviously cannot use pthread_mutexes of pthread_conds since we handle every
1071 scheduling related decision within SimGrid.
1073 In the past (version <=3.3.4) you could do it by playing with
1074 MSG_process_suspend() and MSG_process_resume() or with fake communications (using MSG_task_get(),
1075 MSG_task_put() and MSG_task_Iprobe()).
1077 Since version 3.4, you can use classical synchronization structures. See page \ref XBT_synchro or simply check in
1078 include/xbt/synchro_core.h.
1080 \subsubsection faq_MIA_host_load Where is the get_host_load function hidden in MSG?
1082 There is no such thing because its semantic wouldn't be really
1083 clear. Of course, it is something about the amount of host throughput,
1084 but there is as many definition of "host load" as people asking for
1085 this function. First, you have to remember that resource availability
1086 may vary over time, which make any load notion harder to define.
1088 It may be instantaneous value or an average one. Moreover it may be only the
1089 power of the computer, or may take the background load into account, or may
1090 even take the currently running tasks into account. In some SURF models,
1091 communications have an influence on computational power. Should it be taken
1094 First of all, it's near to impossible to predict the load beforehands in the
1095 simulator since it depends on too much parameters (background load
1096 variation, bandwidth sharing algorithmic complexity) some of them even being
1097 not known beforehands (other task starting at the same time). So, getting
1098 this information is really hard (just like in real life). It's not just that
1099 we want MSG to be as painful as real life. But as it is in some way
1100 realistic, we face some of the same problems as we would face in real life.
1102 How would you do it for real? The most common option is to use something
1103 like NWS that performs active probes. The best solution is probably to do
1104 the same within MSG, as in next code snippet. It is very close from what you
1105 would have to do out of the simulator, and thus gives you information that
1106 you could also get in real settings to not hinder the realism of your
1110 double get_host_load() {
1111 m_task_t task = MSG_task_create("test", 0.001, 0, NULL);
1112 double date = MSG_get_clock();
1114 MSG_task_execute(task);
1115 date = MSG_get_clock() - date;
1116 MSG_task_destroy(task);
1117 return (0.001/date);
1121 Of course, it may not match your personal definition of "host load". In this
1122 case, please detail what you mean on the mailing list, and we will extend
1123 this FAQ section to fit your taste if possible.
1125 \subsubsection faq_MIA_communication_time How can I get the *real* communication time?
1127 Communications are synchronous and thus if you simply get the time
1128 before and after a communication, you'll only get the transmission
1129 time and the time spent to really communicate (it will also take into
1130 account the time spent waiting for the other party to be
1131 ready). However, getting the *real* communication time is not really
1132 hard either. The following solution is a good starting point.
1137 m_task_t task = MSG_task_create("Task", task_comp_size, task_comm_size,
1138 calloc(1,sizeof(double)));
1139 *((double*) task->data) = MSG_get_clock();
1140 MSG_task_put(task, slaves[i % slaves_count], PORT_22);
1141 INFO0("Send completed");
1146 m_task_t task = NULL;
1149 time1 = MSG_get_clock();
1150 a = MSG_task_get(&(task), PORT_22);
1151 time2 = MSG_get_clock();
1152 if(time1<*((double *)task->data))
1153 time1 = *((double *) task->data);
1154 INFO1("Communication time : \"%f\" ", time2-time1);
1156 MSG_task_destroy(task);
1161 \subsection faq_MIA_SimDag SimDag related questions
1163 \subsubsection faq_SG_comm Implementing communication delays between tasks.
1165 A classic question of SimDag newcomers is about how to express a
1166 communication delay between tasks. The thing is that in SimDag, both
1167 computation and communication are seen as tasks. So, if you want to
1168 model a data dependency between two DAG tasks t1 and t2, you have to
1169 create 3 SD_tasks: t1, t2 and c and add dependencies in the following
1173 SD_task_dependency_add(NULL, NULL, t1, c);
1174 SD_task_dependency_add(NULL, NULL, c, t2);
1177 This way task t2 cannot start before the termination of communication c
1178 which in turn cannot start before t1 ends.
1180 When creating task c, you have to associate an amount of data (in bytes)
1181 corresponding to what has to be sent by t1 to t2.
1183 Finally to schedule the communication task c, you have to build a list
1184 comprising the workstations on which t1 and t2 are scheduled (w1 and w2
1185 for example) and build a communication matrix that should look like
1188 \subsubsection faq_SG_DAG How to implement a distributed dynamic scheduler of DAGs.
1190 Distributed is somehow "contagious". If you start making distributed
1191 decisions, there is no way to handle DAGs directly anymore (unless I
1192 am missing something). You have to encode your DAGs in term of
1193 communicating process to make the whole scheduling process
1194 distributed. Here is an example of how you could do that. Assume T1
1195 has to be done before T2.
1198 int your_agent(int argc, char *argv[] {
1200 T1 = MSG_task_create(...);
1201 T2 = MSG_task_create(...);
1205 if(cond) MSG_task_execute(T1);
1207 if((MSG_task_get_remaining_computation(T1)=0.0) && (you_re_in_a_good_mood))
1208 MSG_task_execute(T2)
1210 /* do something else */
1216 If you decide that the distributed part is not that much important and that
1217 DAG is really the level of abstraction you want to work with, then you should
1218 give a try to \ref SD_API.
1220 \subsection faq_MIA_generic Generic features
1222 \subsubsection faq_more_processes Increasing the amount of simulated processes
1224 Here are a few tricks you can apply if you want to increase the amount
1225 of processes in your simulations.
1227 - <b>A few thousands of simulated processes</b> (soft tricks)\n
1228 SimGrid can use either pthreads library or the UNIX98 contextes. On
1229 most systems, the number of pthreads is limited and then your
1230 simulation may be limited for a stupid reason. This is especially
1231 true with the current linux pthreads, and I cannot get more than
1232 2000 simulated processes with pthreads on my box. The UNIX98
1233 contexts allow me to raise the limit to 25,000 simulated processes
1235 The <tt>--with-context</tt> option of the <tt>./configure</tt>
1236 script allows you to choose between UNIX98 contextes
1237 (<tt>--with-context=ucontext</tt>) and the pthread version
1238 (<tt>--with-context=pthread</tt>). The default value is ucontext
1239 when the script detect a working UNIX98 context implementation. On
1240 Windows boxes, the provided value is discarded and an adapted
1241 version is picked up.\n\n
1242 We experienced some issues with contextes on some rare systems
1243 (solaris 8 and lower or old alpha linuxes comes to mind). The main
1244 problem is that the configure script detect the contextes as being
1245 functional when it's not true. If you happen to use such a system,
1246 switch manually to the pthread version, and provide us with a good
1247 patch for the configure script so that it is done automatically ;)
1249 - <b>Hundred thousands of simulated processes</b> (hard-core tricks)\n
1250 As explained above, SimGrid can use UNIX98 contextes to represent
1251 and handle the simulated processes. Thanks to this, the main
1252 limitation to the number of simulated processes becomes the
1253 available memory.\n\n
1254 Here are some tricks I had to use in order to run a token ring
1255 between 25,000 processes on my laptop (1Gb memory, 1.5Gb swap).\n
1256 - First of all, make sure your code runs for a few hundreds
1257 processes before trying to push the limit. Make sure it's
1258 valgrind-clean, ie that valgrind does not report neither memory
1259 error nor memory leaks. Indeed, numerous simulated processes
1260 result in *fat* simulation hindering debugging.
1261 - It was really boring to write 25,000 entries in the deployment
1262 file, so I wrote a little script
1263 <tt>examples/gras/mutual_exclusion/simple_token/make_deployment.pl</tt>, which you may
1264 want to adapt to your case. You could also think about hijacking
1265 the SURFXML parser (have look at \ref faq_flexml_bypassing).
1266 - The deployment file became quite big, so I had to do what is in
1267 the FAQ entry \ref faq_flexml_limit
1268 - Each UNIX98 context has its own stack entry. As debugging this is
1269 quite hairly, the default value is a bit overestimated so that
1270 user don't get into trouble about this. You want to tune this
1271 size to increse the number of processes. This is the
1272 <tt>STACK_SIZE</tt> define in
1273 <tt>src/xbt/xbt_context_sysv.c</tt>, which is 128kb by default.
1274 Reduce this as much as you can, but be warned that if this value
1275 is too low, you'll get a segfault. The token ring example, which
1276 is quite simple, runs with 40kb stacks.
1277 - You may tweak the logs to reduce the stack size further. When
1278 logging something, we try to build the string to display in a
1279 char array on the stack. The size of this array is constant (and
1280 equal to XBT_LOG_BUFF_SIZE, defined in include/xbt/log/h). If the
1281 string is too large to fit this buffer, we move to a dynamically
1282 sized buffer. In which case, we have to traverse one time the log
1283 event arguments to compute the size we need for the buffer,
1284 malloc it, and traverse the argument list again to do the actual
1286 The idea here is to move XBT_LOG_BUFF_SIZE to 1, forcing the logs
1287 to use a dynamic array each time. This allows us to lower further
1288 the stack size at the price of some performance loss...\n
1289 This allowed me to run the reduce the stack size to ... 4k. Ie,
1290 on my 1Gb laptop, I can run more than 250,000 processes!
1292 \subsubsection faq_MIA_batch_scheduler Is there a native support for batch schedulers in SimGrid?
1294 No, there is no native support for batch schedulers and none is
1295 planned because this is a very specific need (and doing it in a
1296 generic way is thus very hard). However some people have implemented
1297 their own batch schedulers. Vincent Garonne wrote one during his PhD
1298 and put his code in the contrib directory of our SVN so that other can
1299 keep working on it. You may find inspiring ideas in it.
1301 \subsubsection faq_MIA_checkpointing I need a checkpointing thing
1303 Actually, it depends on whether you want to checkpoint the simulation, or to
1304 simulate checkpoints.
1306 The first one could help if your simulation is a long standing process you
1307 want to keep running even on hardware issues. It could also help to
1308 <i>rewind</i> the simulation by jumping sometimes on an old checkpoint to
1309 cancel recent calculations.\n
1310 Unfortunately, such thing will probably never exist in SG. One would have to
1311 duplicate all data structures because doing a rewind at the simulator level
1312 is very very hard (not talking about the malloc free operations that might
1313 have been done in between). Instead, you may be interested in the Libckpt
1314 library (http://www.cs.utk.edu/~plank/plank/www/libckpt.html). This is the
1315 checkpointing solution used in the condor project, for example. It makes it
1316 easy to create checkpoints (at the OS level, creating something like core
1317 files), and rerunning them on need.
1319 If you want to simulate checkpoints instead, it means that you want the
1320 state of an executing task (in particular, the progress made towards
1321 completion) to be saved somewhere. So if a host (and the task executing on
1322 it) fails (cf. #MSG_HOST_FAILURE), then the task can be restarted
1323 from the last checkpoint.\n
1325 Actually, such a thing does not exists in SimGrid either, but it's just
1326 because we don't think it is fundamental and it may be done in the user code
1327 at relatively low cost. You could for example use a watcher that
1328 periodically get the remaining amount of things to do (using
1329 MSG_task_get_remaining_computation()), or fragment the task in smaller
1332 \subsection faq_platform Platform building and Dynamic resources
1334 \subsubsection faq_platform_example Where can I find SimGrid platform files?
1336 There is several little examples in the archive, in the examples/msg
1337 directory. From time to time, we are asked for other files, but we
1338 don't have much at hand right now.
1340 You should refer to the Platform Description Archive
1341 (http://pda.gforge.inria.fr) project to see the other platform file we
1342 have available, as well as the Simulacrum simulator, meant to generate
1343 SimGrid platforms using all classical generation algorithms.
1345 \subsubsection faq_platform_alnem How can I automatically map an existing platform?
1347 We are working on a project called ALNeM (Application-Level Network
1348 Mapper) which goal is to automatically discover the topology of an
1349 existing network. Its output will be a platform description file
1350 following the SimGrid syntax, so everybody will get the ability to map
1351 their own lab network (and contribute them to the catalog project).
1352 This tool is not ready yet, but it move quite fast forward. Just stay
1355 \subsubsection faq_platform_synthetic Generating synthetic but realistic platforms
1357 The third possibility to get a platform file (after manual or
1358 automatic mapping of real platforms) is to generate synthetic
1359 platforms. Getting a realistic result is not a trivial task, and
1360 moreover, nobody is really able to define what "realistic" means when
1361 speaking of topology files. You can find some more thoughts on this
1363 <a href="http://graal.ens-lyon.fr/~alegrand/articles/Simgrid-Introduction.pdf">slides</a>.
1365 If you are looking for an actual tool, there we have a little tool to
1366 annotate Tiers-generated topologies. This perl-script is in
1367 <tt>tools/platform_generation/</tt> directory of the SVN. Dinda et Al.
1368 released a very comparable tool, and called it GridG.
1370 \subsubsection faq_SURF_multicore Modeling multi-core resources
1372 There is currently no native support for multi-core or SMP machines in
1373 SimGrid. We are currently working on it, but coming up with the right
1374 model is very hard: Cores share caches and bus to access memory and
1375 thus interfere with each others. Memory contention is a crucial
1376 component of multi-core modeling.
1378 In the meanwhile, some user-level tricks can reveal sufficient for
1379 you. For example, you may model each core by a CPU and add some very
1380 high speed links between them. This complicates a bit the user code
1381 since you have to remember that when you assign something to a (real)
1382 host, it can be any of the (fake) hosts representing the cores of a
1383 given machine. For that, you can use the prop tag of the XML files as
1384 follows. Your code should then look at the ‘machine’ property
1385 associated with each workstation, and run parallel tasks over all
1386 cores of the machine.
1389 <host id="machine0/core0" power="91500E6">
1390 <prop id="machine" value="machine0"/>
1391 <prop id="core" value="0"/>
1393 <host id="machine0/core1" power="91500E6">
1394 <prop id="machine" value="machine0"/>
1395 <prop id="core" value="1"/>
1401 \subsubsection faq_SURF_dynamic Modeling dynamic resource availability
1403 A nice feature of SimGrid is that it enables you to seamlessly have
1404 resources whose availability change over time. When you build a
1405 platform, you generally declare hosts like that:
1408 <host id="host A" power="100.00"/>
1411 If you want the availability of "host A" to change over time, the only
1412 thing you have to do is change this definition like that:
1415 <host id="host A" power="100.00" availability_file="trace_A.txt" state_file="trace_A_failure.txt"/>
1418 For hosts, availability files are expressed in fraction of available
1419 power. Let's have a look at what "trace_A.txt" may look like:
1428 At time 0, our host will deliver 100 flop/s. At time 11.0, it will
1429 deliver only 50 flop/s until time 20.0 where it will will start
1430 delivering 90 flop/s. Last at time 21.0 (20.0 plus the periodicity
1431 1.0), we'll be back to the beginning and it will deliver 100 flop/s.
1433 Now let's look at the state file:
1440 A negative value means "off" while a positive one means "on". At time
1441 1.0, the host is on. At time 1.0, it is turned off and at time 2.0, it
1442 is turned on again until time 12 (2.0 plus the periodicity 10.0). It
1443 will be turned on again at time 13.0 until time 23.0, and so on.
1445 Now, let's look how the same kind of thing can be done for network
1446 links. A usual declaration looks like:
1449 <link id="LinkA" bandwidth="10.0" latency="0.2"/>
1452 You have at your disposal the following options: bandwidth_file,
1453 latency_file and state_file. The only difference with hosts is that
1454 bandwidth_file and latency_file do not express fraction of available
1455 power but are expressed directly in bytes per seconds and seconds.
1457 \subsubsection faq_platform_multipath How to express multipath routing in platform files?
1459 It is unfortunately impossible to express the fact that there is more
1460 than one routing path between two given hosts. Let's consider the
1461 following platform file:
1464 <route src="A" dst="B">
1467 <route src="B" dst="C">
1470 <route src="A" dst="C">
1475 Although it is perfectly valid, it does not mean that data traveling
1476 from A to C can either go directly (using link 3) or through B (using
1477 links 1 and 2). It simply means that the routing on the graph is not
1478 trivial, and that data do not following the shortest path in number of
1479 hops on this graph. Another way to say it is that there is no implicit
1480 in these routing descriptions. The system will only use the routes you
1481 declare (such as <route src="A" dst="C"><link:ctn
1482 id="3"/></route>), without trying to build new routes by aggregating
1485 You are also free to declare platform where the routing is not
1486 symmetric. For example, add the following to the previous file:
1489 <route src="C" dst="A">
1495 This makes sure that data from C to A go through B where data from A
1496 to C go directly. Don't worry about realism of such settings since
1497 we've seen ways more weird situation in real settings (in fact, that's
1498 the realism of very regular platforms which is questionable, but
1499 that's another story).
1501 \subsubsection faq_flexml_bypassing Bypassing the XML parser with your own C functions
1503 So you want to bypass the XML files parser, uh? Maybe doing some parameter
1504 sweep experiments on your simulations or so? This is possible, and
1505 it's not even really difficult (well. Such a brutal idea could be
1506 harder to implement). Here is how it goes.
1508 For this, you have to first remember that the XML parsing in SimGrid is done
1509 using a tool called FleXML. Given a DTD, this gives a flex-based parser. If
1510 you want to bypass the parser, you need to provide some code mimicking what
1511 it does and replacing it in its interactions with the SURF code. So, let's
1512 have a look at these interactions.
1514 FleXML parser are close to classical SAX parsers. It means that a
1515 well-formed SimGrid platform XML file might result in the following
1518 - start "platform_description" with attribute version="2"
1519 - start "host" with attributes id="host1" power="1.0"
1521 - start "host" with attributes id="host2" power="2.0"
1523 - start "link" with ...
1525 - start "route" with ...
1526 - start "link:ctn" with ...
1529 - end "platform_description"
1531 The communication from the parser to the SURF code uses two means:
1532 Attributes get copied into some global variables, and a surf-provided
1533 function gets called by the parser for each event. For example, the event
1534 - start "host" with attributes id="host1" power="1.0"
1536 let the parser do something roughly equivalent to:
1538 strcpy(A_host_id,"host1");
1543 In SURF, we attach callbacks to the different events by initializing the
1544 pointer functions to some the right surf functions. Since there can be
1545 more than one callback attached to the same event (if more than one
1546 model is in use, for example), they are stored in a dynar. Example in
1547 workstation_ptask_L07.c:
1549 /* Adding callback functions */
1550 surf_parse_reset_parser();
1551 surfxml_add_callback(STag_surfxml_host_cb_list, &parse_cpu_init);
1552 surfxml_add_callback(STag_surfxml_prop_cb_list, &parse_properties);
1553 surfxml_add_callback(STag_surfxml_link_cb_list, &parse_link_init);
1554 surfxml_add_callback(STag_surfxml_route_cb_list, &parse_route_set_endpoints);
1555 surfxml_add_callback(ETag_surfxml_link_c_ctn_cb_list, &parse_route_elem);
1556 surfxml_add_callback(ETag_surfxml_route_cb_list, &parse_route_set_route);
1558 /* Parse the file */
1559 surf_parse_open(file);
1560 xbt_assert1((!surf_parse()), "Parse error in %s", file);
1564 So, to bypass the FleXML parser, you need to write your own version of the
1565 surf_parse function, which should do the following:
1566 - Fill the A_<tag>_<attribute> variables with the wanted values
1567 - Call the corresponding STag_<tag>_fun function to simulate tag start
1568 - Call the corresponding ETag_<tag>_fun function to simulate tag end
1569 - (do the same for the next set of values, and loop)
1571 Then, tell SimGrid that you want to use your own "parser" instead of the stock one:
1573 surf_parse = surf_parse_bypass_environment;
1574 MSG_create_environment(NULL);
1575 surf_parse = surf_parse_bypass_application;
1576 MSG_launch_application(NULL);
1579 A set of macros are provided at the end of
1580 include/surf/surfxml_parse.h to ease the writing of the bypass
1581 functions. An example of this trick is distributed in the file
1582 examples/msg/masterslave/masterslave_bypass.c
1584 \subsection faq_simgrid_configuration Changing SimGrid's behavior
1586 A number of options can be given at runtime to change the default
1587 SimGrid behavior. In particular, you can change the default cpu and
1590 \subsubsection faq_simgrid_configuration_fullduplex Using Fullduplex
1592 Experimental fullduplex support is now available on the svn branch. In order to fullduple to work your platform must have two links for each pair
1593 of interconnected hosts, see an example here:
1595 simgrid_svn_sources/exemples/msg/gtnets/fullduplex-p.xml
1598 Using fullduplex support ongoing and incoming communication flows are
1599 treated independently for most models. The exception is the LV08 model which
1600 adds 0.05 of usage on the opposite direction for each new created flow. This
1601 can be useful to simulate some important TCP phenomena such as ack compression.
1603 Running a fullduplex example:
1605 cd simgrid_svn_sources/exemples/msg/gtnets
1606 ./gtnets fullduplex-p.xml fullduplex-d.xml --cfg=fullduplex:1
1613 \subsubsection faq_simgrid_configuration_gtnets Using GTNetS
1615 It is possible to use a packet-level network simulator
1616 instead of the default flow-based simulation. You may want to use such
1617 an approach if you have doubts about the validity of the default model
1618 or if you want to perform some validation experiments. At the moment,
1619 we support the GTNetS simulator (it is still rather experimental
1620 though, so leave us a message if you play with it).
1624 To enable GTNetS model inside SimGrid it is needed to patch the GTNetS simulator source code
1625 and build/install it from scratch
1628 - <b>Download and enter the recent downloaded GTNetS directory</b>
1631 svn checkout svn://scm.gforge.inria.fr/svn/simgrid/contrib/trunk/GTNetS/
1636 - <b>Use the following commands to unzip and patch GTNetS package to work within SimGrid.</b>
1639 unzip gtnets-current.zip
1640 tar zxvf gtnets-current-patch.tgz
1642 cat ../00*.patch | patch -p1
1645 - <b>OPTIONALLY</b> you can use a patch for itanium 64bit processor family.
1648 cat ../AMD64-FATAL-Removed-DUL_SIZE_DIFF-Added-fPIC-compillin.patch | patch -p1
1651 - <b>Compile GTNetS</b>
1653 Due to portability issues it is possible that GTNetS does not compile in your architecture. The patches furnished in SimGrid SVN repository are intended for use in Linux architecture only. Unfortunately, we do not have the time, the money, neither the manpower to guarantee GTNetS portability. We advice you to use one of GTNetS communication channel to get more help in compiling GTNetS.
1657 ln -sf Makefile.linux Makefile
1663 - <b>NOTE</b> A lot of warnings are expected but the application should compile
1664 just fine. If the makefile insists in compiling some QT libraries
1665 please try a make clean before asking for help.
1668 - <b>To compile optimized version</b>
1675 - <b>Installing GTNetS</b>
1677 It is important to put the full path of your libgtsim-xxxx.so file when creating the symbolic link. Replace < userhome > by some path you have write access to.
1680 ln -sf /<absolute_path>/gtnets_current/libgtsim-debug.so /<userhome>/usr/lib/libgtnets.so
1681 export LD_LIBRARY_PATH=$LD_LIBRARY_PATH:/<userhome>/usr/lib/libgtnets.so
1682 mkdir /<userhome>/usr/include/gtnets
1683 cp -fr SRC/*.h /<userhome>/usr/include/gtnets
1687 - <b>Enable GTNetS support in SimGrid</b>
1689 In order to enable gtnets with simgrid you have to give where is gtnets. (path to <gtnets_path>/lib and <gtnets_path>/include)
1692 Since v3.4 (with cmake)
1693 cmake . -Dgtnets_path=/<userhome>/usr
1695 Until v3.4 (with autotools)
1696 ./configure --with-gtnets=/<userhome>/usr
1699 - <b>Once you have followed all the instructions for compiling and
1700 installing successfully you can activate this feature at
1701 runntime with the following options:</b>
1704 Since v3.4 (with cmake)
1709 Until v3.4 (with autotools)
1710 cd simgrid/example/msg/
1716 - <b>Or try the GTNetS model dogbone example with</b>
1719 gtnets/gtnets gtnets/onelink-p.xml gtnets/onelink-d.xml --cfg=network_model:GTNets
1723 A long version of this <a href="http://gforge.inria.fr/docman/view.php/12/6283/GTNetS HowTo.html">HowTo</a> it is available
1726 More about GTNetS simulator at <a href="http://www.ece.gatech.edu/research/labs/MANIACS/GTNetS/index.html">GTNetS Website</a>
1730 The patches provided by us worked successfully with GTNetS found
1731 <a href="http://www.ece.gatech.edu/research/labs/MANIACS/GTNetS/software/gtnets-current.zip">here</a>,
1732 dated from 12th June 2008. Due to the discontinuing development of
1733 GTNetS it is impossible to precise a version number. We STRONGLY recommend you
1734 to download and install the GTNetS version found in SimGrid repository as explained above.
1739 \subsubsection faq_simgrid_configuration_alternate_network Using alternative flow models
1741 The default simgrid network model uses a max-min based approach as
1742 explained in the research report
1743 <a href="ftp://ftp.ens-lyon.fr/pub/LIP/Rapports/RR/RR2002/RR2002-40.ps.gz">A Network Model for Simulation of Grid Application</a>.
1744 Other models have been proposed and implemented since then (see for example
1745 <a href="http://mescal.imag.fr/membres/arnaud.legrand/articles/simutools09.pdf">Accuracy Study and Improvement of Network Simulation in the SimGrid Framework</a>)
1746 and can be activated at runtime. For example:
1748 ./mycode platform.xml deployment.xml --cfg=workstation/model:compound --cfg=network/model:LV08 -cfg=cpu/model:Cas01
1751 Possible models for the network are currently "Constant", "CM02",
1752 "LegrandVelho", "GTNets", Reno", "Reno2", "Vegas". Others will
1753 probably be added in the future and many of the previous ones are
1754 experimental and are likely to disappear without notice... To know the
1755 list of the currently implemented models, you should use the
1756 --help-models command line option.
1759 ./masterslave_forwarder ../small_platform.xml deployment_masterslave.xml --help-models
1760 Long description of the workstation models accepted by this simulator:
1761 CLM03: Default workstation model, using LV08 and CM02 as network and CPU
1762 compound: Workstation model allowing you to use other network and CPU models
1763 ptask_L07: Workstation model with better parallel task modeling
1764 Long description of the CPU models accepted by this simulator:
1765 Cas01_fullupdate: CPU classical model time=size/power
1766 Cas01: Variation of Cas01_fullupdate with partial invalidation optimization of lmm system. Should produce the same values, only faster
1767 CpuTI: Variation of Cas01 with also trace integration. Should produce the same values, only faster if you use availability traces
1768 Long description of the network models accepted by this simulator:
1769 Constant: Simplistic network model where all communication take a constant time (one second)
1770 CM02: Realistic network model with lmm_solve and no correction factors
1771 LV08: Realistic network model with lmm_solve and these correction factors: latency*=10.4, bandwidth*=.92, S=8775
1772 Reno: Model using lagrange_solve instead of lmm_solve (experts only)
1773 Reno2: Model using lagrange_solve instead of lmm_solve (experts only)
1774 Vegas: Model using lagrange_solve instead of lmm_solve (experts only)
1777 \subsection faq_tracing Tracing Simulations for Visualization
1779 The trace visualization is widely used to observe and understand the behavior
1780 of parallel applications and distributed algorithms. Usually, this is done in a
1781 two-step fashion: the user instruments the application and the traces are
1782 analyzed after the end of the execution. The visualization itself can highlights
1783 unexpected behaviors, bottlenecks and sometimes can be used to correct
1784 distributed algorithms. The SimGrid team is currently instrumenting the library
1785 in order to let users trace their simulations and analyze them. This part of the
1786 user manual explains how the tracing-related features can be enabled and used
1787 during the development of simulators using the SimGrid library.
1789 \subsubsection faq_tracing_howitworks How it works
1791 For now, the SimGrid library is instrumented so users can trace the <b>platform
1792 utilization</b> using the MSG interface. This means that the tracing will
1793 register how much power is used for each host and how much bandwidth is used for
1794 each link of the platform. The idea with this type of tracing is to observe the
1795 overall view of resources utilization in the first place, especially the
1796 identification of bottlenecks, load-balancing among hosts, and so on.
1798 The idea of the instrumentation is to classify the MSG tasks by category,
1800 the platform utilization (hosts and links) for each of the categories. For that,
1801 the tracing interface enables the declaration of categories and a function to
1802 mark a task with a previously declared category. <em>The tasks that are not
1803 classified according to a category are not traced</em>.
1805 \subsubsection faq_tracing_enabling Enabling using CMake
1807 With the sources of SimGrid, it is possible to enable the tracing
1808 using the parameter <b>-Dtracing=on</b> when the cmake is executed.
1809 The section \ref faq_tracing_functions describes all the functions available
1810 when this Cmake options is activated. These functions will have no effect
1811 if SimGrid is configured without this option (they are wiped-out by the
1815 $ cmake -Dtracing=on .
1819 \subsubsection faq_tracing_functions Tracing Functions
1821 \subsubsubsection Mandatory Functions
1823 \li <b>\c TRACE_start ()</b>: This is the first function to
1824 be called. It returns 0 if everything was properly initialized, 1 otherwise.
1825 All trace functions called before TRACE_start do nothing.
1827 \li <b>\c TRACE_category (const char *category)</b>: This function should be used
1828 to define a user category. The category can be used to differentiate the tasks
1829 that are created during the simulation (for example, tasks from server1,
1830 server2, or request tasks, computation tasks, communication tasks).
1831 All resource utilization (host power and link bandwidth) will be
1832 classified according to the task category. Tasks that do not belong to a
1833 category are not traced.
1835 \li <b>\c TRACE_msg_set_task_category (m_task_t task, const char *category)</b>:
1836 This function should be called after the creation of a task, to define the
1837 category of that task. The first parameter \c task must contain a task that was
1838 created with the function \c MSG_task_create. The second parameter
1839 \c category must contain a category that was previously defined by the function
1842 \li <b>\c TRACE_end ()</b>: This is the last function to be called. It closes
1843 the trace file and stops the tracing of the simulation. All tracing will be
1844 completely disabled after the calling this function. Although we recommend
1845 the use of this function somewhere in the end of program, it can be used
1846 anywhere in the code. This function returns 0 if everything is ok, 1 otherwise.
1848 \subsubsubsection Optional Functions
1850 \li <b>\c TRACE_host_variable_declare (const char *variable)</b>:
1851 Declare a user variable that will be associated to hosts. A variable can
1852 be used to trace user variables such as the number of tasks in a server,
1853 the number of clients in an application, and so on.
1855 \li <b>\c TRACE_host_variable_[set|add|sub] (const char *variable, double
1857 Set the value of a given user variable. It is important to remind that
1858 the value of this variable is always associated to the host. The host
1859 that will be used when these functions are called is the one returned by
1860 the function \c MSG_host_self().
1862 \subsubsection faq_tracing_options Tracing configuration Options
1864 These are the options accepted by the tracing system of SimGrid:
1866 \li <b>\c tracing/filename</b>: use this to specify the name of the trace file
1867 that will be created during the simulation. For example, after the binary
1868 of your simulator, you can pass as parameter this:
1870 --cfg=tracing/filename:mytracefile.trace
1872 in order to trace the behavior of the simulation in a file with the name
1875 \li <b>\c tracing/platform</b>: use this to activate the tracing of the
1876 platform. For example, you can pass as parameter to your simulator:
1878 --cfg=tracing/platform:1
1880 to trace the platform utilization by the categories you declared in your
1881 simulator. By default, this options is set to 0.
1883 \subsubsection faq_tracing_example Example of Instrumentation
1885 A simplified example using the tracing mandatory functions.
1888 int main (int argc, char **argv)
1890 MSG_global_init (&argc, &argv);
1892 //note that TRACE_start must be called after MSG_global_init
1894 TRACE_category ("request");
1895 TRACE_category ("computation");
1896 TRACE_category ("finalize");
1898 //(... after deployment ...)
1900 m_task_t req1 = MSG_task_create("1st_request_task", 10, 10, NULL);
1901 m_task_t req2 = MSG_task_create("2nd_request_task", 10, 10, NULL);
1902 m_task_t req3 = MSG_task_create("3rd_request_task", 10, 10, NULL);
1903 m_task_t req4 = MSG_task_create("4th_request_task", 10, 10, NULL);
1904 TRACE_msg_set_task_category (req1, "request");
1905 TRACE_msg_set_task_category (req2, "request");
1906 TRACE_msg_set_task_category (req3, "request");
1907 TRACE_msg_set_task_category (req4, "request");
1909 m_task_t comp = MSG_task_create ("comp_task", 100, 100, NULL);
1910 TRACE_msg_set_task_category (comp, "computation");
1912 m_task_t finalize = MSG_task_create ("finalize", 0, 0, NULL);
1913 TRACE_msg_set_task_category (finalize, "finalize");
1924 \subsubsection faq_tracing_analyzing Analyzing the SimGrid Traces
1926 The SimGrid library, during an instrumented simulation, creates a trace file in
1927 the Paje file format that contains the platform utilization for the simulation
1928 that was executed. The visualization analysis of this file is performed with the
1929 visualization tool <a href="http://triva.gforge.inria.fr">Triva</a>, with
1930 special configurations tunned to SimGrid needs. This part of the documentation
1931 explains how to configure and use Triva to analyse a SimGrid trace file.
1933 - <b>Installing Triva</b>: the tool is available in the INRIAGforge,
1934 at <a href="http://triva.gforge.inria.fr">http://triva.gforge.inria.fr</a>.
1935 Use the following command to get the sources, and then check the file
1936 <i>INSTALL.simplified</i>. This file contains instructions to install
1937 the tool's dependencies in a Ubuntu/Debian Linux.
1939 $ svn checkout svn://scm.gforge.inria.fr/svn/triva
1941 $ cat INSTALL.simplified
1944 - <b>Executing Triva</b>: a binary called <i>Triva</i> is available after the
1945 installation (you can execute it passing <em>--help</em> to check its
1946 options). If the triva binary is not available after following the
1947 installation instructions, you may want to execute the following command to
1948 initialize the GNUstep environment variables (note that the location of the
1949 <i>GNUstep.sh</i> file may vary depending on your GNUstep installation - the
1950 command is known to work in Ubuntu and Debian Linux):
1952 $ source /usr/share/GNUstep/Makefiles/GNUstep.sh
1954 You should be able to see this output after the installation of triva:
1956 $ ./Triva.app/Triva --help
1957 Usage: Triva [OPTION...] TRACEFILE
1958 Trace Analysis through Visualization
1960 You need to use one of the following options:
1961 -g, --graph Graph Analysis
1962 -t, --treemap Treemap Analysis
1964 Other auxiliary options to check the trace file:
1965 -c, --check Check the integrity of trace file
1966 -h, --hierarchy Export the trace type hierarchy
1967 -l, --list List entity types
1969 -?, --help Give this help list
1970 --usage Give a short usage message
1972 Triva expects that the user choose one of the available options
1973 (currently <em>--graph</em> or <em>--treemap</em> for a visualization analysis)
1974 and the trace file from the simulation.
1976 - <b>Understanding Triva - time-slice</b>: the analysis of a trace file using
1977 the tool always takes into account the concept of the <em>time-slice</em>.
1978 This concept means that what is being visualized in the screen is always
1979 calculated considering a specific time frame, with its beggining and end
1980 timestamp. The time-slice is configured by the user and can be changed
1981 dynamically through the window called <em>Time Interval</em> that is opened
1982 whenever a trace file is being analyzed. The next figure depicts the time-slice
1983 configuration window.
1984 In the top of the window, in the space named <i>Trace Time</i>,
1985 the two fields show the beggining of the trace (which usually starts in 0) and
1986 the end (that depends on the time simulated by SimGrid). The middle of the
1987 window, in the square named <i>Time Slice Configuration</i>, contains the
1988 aspects related to the time-slice, including its <i>start</i> and its
1989 <i>size</i>. The gray rectangle in the bottom of this part indicates the
1990 <i>current time-slice</i> that is considered for the drawings. If the checkbox
1991 <i>Update Drawings on Sliders Change</i> is not selected, the button
1992 <i>Apply</i> must be clicked in order to inform triva that the
1993 new time-slice must be considered. The bottom part of the window, in the space
1994 indicated by the square <i>Time Slice Animation</i> can be used to advance
1995 the time-frame automatically. The user configures the amount of time that the
1996 time-frame will forward and how frequent this update will happen. Once this is
1997 configured, the user clicks the <i>Play</i> button in order to see the dynamic
1998 changes on the drawings.
2001 <a href="triva-time_interval.png" border=0><img src="triva-time_interval.png" width="50%" border=0></a>
2004 <b>Remarks:</b> when the trace has too many hosts or links, the computation to
2005 take into account a new time-slice can be expensive. When this happens, the
2006 <i>Frequency</i> parameter, but also updates caused by change on configurations
2007 when the checkbox <i>Update Drawings on Sliders
2008 Change</i> is selected will not be followed.
2010 - <b>Understanding Triva - graph</b>: this part of the documention explains how
2011 to analyze the traces using the graph view of Triva, when the user executes
2012 the tool passing <em>--graph</em> as parameter. Triva opens three windows when
2013 this parameter is used: the <i>Time Interval</i> window (previously described),
2014 the <i>Graph Representation</i> window, and the <em>Graph Configuration</em>
2015 window. The Graph Representation is the window where drawings take place.
2016 Initially, it is completely white waiting for a proper graph configuration input
2017 by the user. We start the description of this type of analysis by describing the
2018 <i>Graph Configuration</i> window (depicted below). By using a particular
2019 configuration, triva
2020 can be used to customize the graph drawing according to
2021 the SimGrid trace that was created with user-specific categories. Before delving
2022 into the details of this customization, let us first explain the major parts of
2023 the graph configuration window. The buttons located in the top-right corner can
2024 be used to delete, copy and create a new configuration. The checkbox in the
2025 top-middle part of the window indicates if the configuration typed in the
2026 textfield is syntactically correct (we are using the non-XML
2027 <a href="http://en.wikipedia.org/wiki/Property_list">Property List Format</a> to
2028 describe the configuration). The pop-up button located on the top-left corner
2029 indicates the selected configuration (the user can have multiple graph
2030 configurations). The bottom-left text field contains the name of the current
2031 configuration (updates on this field must be followed by typing enter on the
2032 keyboard to take into account the name change). The bottom-right <em>Apply</em>
2033 button activates the current configuration, resulting on an update on the graph
2037 <a href="triva-graph_configuration.png" border=0><img src="triva-graph_configuration.png" width="50%" border=0></a>
2040 <b>Basic SimGrid Configuration</b>: The figure shows in the big textfield the
2041 basic configuration that should be used during the analysis of a SimGrid trace
2042 file. The basic logic of the configuration is as follows:
2048 The nodes of the graph will be created based on the <i>node</i> parameter, which
2049 in this case is the different <em>"HOST"</em>s of the platform
2050 used to simulate. The <i>edge</i> parameter indicates that the edges of the
2051 graph will be created based on the <em>"LINK"</em>s of the platform. After the
2052 definition of these two parameters, the configuration must detail how
2053 <em>HOST</em>s and <em>LINK</em>s should be drawn. For that, the configuration
2054 must have an entry for each of the types used. For <em>HOST</em>, as basic
2055 configuration, we have:
2062 The parameter <em>size</em> indicates which variable from the trace file will be
2063 used to define the size of the node HOST in the visualization. If the simulation
2064 was executed with availability traces, the size of the nodes will be changed
2065 according to these traces. The parameter <em>scale</em> indicates if the value
2066 of the variable is <em>global</em> or <em>local</em>. If it is global, the value
2067 will be relative to the power of all other hosts, if it is local, the value will
2068 be relative locally.
2069 For <em>LINK</em> we have:
2079 For the types specified in the <em>edge</em> parameter (such as <em>LINK</em>),
2080 the configuration must contain two additional parameters: <em>src</em> and
2081 <em>dst</em> that are used to properly identify which nodes this edge is
2082 connecting. The values <em>source</em> and <em>destination</em> are always present
2083 in the SimGrid trace file and should not be changed in the configuration. The
2084 parameter <em>size</em> for the LINK, in this case, is configured as the
2085 variable <em>bandwidth</em>, with a <em>global</em> scale. The scale meaning
2086 here is exactly the same used for nodes. The last parameter is the GraphViz
2087 algorithm used to calculate the position of the nodes in the graph
2090 graphviz-algorithm = neato;
2093 <b>Customizing the Graph Representation</b>: triva is capable to handle
2094 a customized graph representation based on the variables present in the trace
2095 file. In the case of SimGrid, every time a category is created for tasks, two
2096 variables in the trace file are defined: one to indicate node utilization (how
2097 much power was used by that task category), and another to indicate link
2098 utilization (how much bandwidth was used by that category). For instance, if the
2099 user declares a category named <i>request</i>, there will be variables named
2100 <b>p</b><i>request</i> and a <b>b</b><i>request</i> (<b>p</b> for power and
2101 <b>b</b> for bandwidth). It is important to notice that the variable
2102 <i>prequest</i> in this case is only available for HOST, and
2103 <i>brequest</i> is only available for LINK. <b>Example</b>: suppose there are
2104 two categories for tasks: request and compute. To create a customized graph
2105 representation with a proportional separation of host and link utilization, use
2106 as configuration for HOST and LINK this:
2115 values = (prequest, pcomputation);
2128 values = (brequest, bcomputation);
2132 Where <i>sep_host</i> contains a composition of type <i>separation</i> where
2133 its max size is the <i>power</i> of the host and the variables <i>prequest</i>
2134 and <i>pcomputation</i> are drawn proportionally to the size of the HOST. And
2135 <i>sep_link</i> is also a separation where max is defined as the
2136 <i>bandwidth</i> of the link, and the variables <i>brequest</i> and
2137 <i>bcomputation</i> are drawn proportionally within a LINK.
2138 <i>This configuration enables the analysis of resource utilization by MSG tasks,
2139 and the identification of load-balancing issues, network bottlenecks, for
2141 <b>Other compositions</b>: besides <i>separation</i>, it is possible to use
2142 other types of compositions, such as gradients, and colors, like this:
2147 values = (numberOfTasks);
2151 values = (is_server);
2154 Where <i>gra_host</i> creates a gradient within a node of the graph, using a
2155 global scale and using as value a variable called <i>numberOfTasks</i>, that
2156 could be declared by the user using the optional tracing functions of SimGrid.
2157 If scale is global, the max and min value for the gradient will be equal to the
2158 max and min numberOfTasks among all hosts, and if scale is local, the max and
2159 min value based on the value of numberOfTasks locally in each host.
2160 And <i>color_host</i> composition draws a square based on a positive value of
2161 the variable <i>is_server</i>, that could also be defined by the user using the
2162 SimGrid tracing functions. \n
2163 <b>The Graph Visualization</b>: The next figure shows a graph visualization of a
2164 given time-slice of the masterslave_forwarder example (present in the SimGrid
2165 sources). The red color indicates tasks from the <i>compute</i> category. This
2166 visualization was generated with the following configuration:
2179 values = (pcompute, pfinalize);
2191 values = (bcompute, bfinalize);
2194 graphviz-algorithm = neato;
2199 <a href="triva-graph_visualization.png" border=0><img src="triva-graph_visualization.png" width="50%" border=0></a>
2203 - <b>Understading Triva - colors</b>: An important issue when using Triva is how
2204 to define colors. To do that, we have to know which variables are defined in
2205 the trace file generated by the SimGrid library. The parameter <em>--list</em>
2206 lists the variables for a given trace file:
2208 $ Triva -l masterslave_forwarder.trace
2226 We can see that HOST has seven variables (from power to pfinalize) and LINK has
2227 four (from bandwidth to bfinalize). To define a red color for the
2228 <i>pcompute</i> and <i>bcompute</i> (which are defined based on user category
2229 <i>compute</i>), execute:
2231 $ defaults write Triva 'pcompute Color' '1 0 0'
2232 $ defaults write Triva 'bcompute Color' '1 0 0'
2234 Where the three numbers in each line are the RGB color with values from 0 to 1.
2236 \subsection faq_modelchecking Model-Checking
2237 \subsubsection faq_modelchecking_howto How to use it
2238 To enable the experimental SimGrid model-checking support the program should
2239 be executed with the command line argument
2243 Properties are expressed as assertions using the function
2245 void MC_assert(int prop);
2248 \subsection faq_binding_lua Lua Binding
2249 Most of Simgrid modules require a good level in C programming, since simgrid is used to be as standard C library.
2250 Sometime users prefer using some kind of « easy scripts » or a language easier to code with, for their works,
2251 which avoid dealing with C errors, and sometime an important gain of time.
2252 Besides Java Binding, Lua and Ruby bindings are available since version 3.4 of Simgrid
2253 for MSG Module, and we are currenlty working on bindings for other modules.
2256 \subsubsection faq_binding_lua_about What is lua ?
2257 Lua is a lightweight, reflective, imperative and functional programming language,
2258 designed as a scripting language with extensible semantics as a primary goal (see official web site <a href="http://www.lua.org">here</a>).
2259 \subsubsection faq_binding_lua_why Why lua ?
2260 Lua is a fast, portable and powerful script language, quite simple to use for developpers.
2261 it combines procedural features with powerful data description facilities,
2262 by using a simple, yet powerful, mechanism of tables.
2263 Lua has a relatively simple C API compared to other scripting languages,
2264 and accordingly it provides a robust, easy to use it.
2265 \subsubsection faq_binding_lua_simgrid How to use lua in Simgrid ?
2266 Actually, the use of lua in Simgrid is quite simple, you have just to follow the same steps as coding with C in Simgird :
2267 - Coding functions coresponding to each process
2268 - loading the platforme/deployment XML file that describe the environment of simulation
2269 - and … Running the Simulation.
2271 \dontinclude lua/master_slave.lua
2272 \subsubsection faq_binding_lua_example_master_slave Master/Slave Example
2275 \until end_of_master
2276 we mainly use simgrid.Task.new(task_name,computation_size,communication_size) to create our MSG Task,
2277 then simgrid.Task.send(task,alias) to send it.
2278 we use also simgrid.Task.name(task), to get the task's name.
2282 Here, we see the use of simgrid.Task.recv(alias) to receive a task with a specific alias,
2283 this function return directly the task recevied.
2285 \li Set Environmenet and run application
2286 \until simgrid.clean()
2288 \subsubsection faq_binding_lua_example_data Exchanging Data
2289 You can also exchange data between Process using lua. for that, you have to deal with lua task as a table,
2290 since lua is based itself on a mechanism of tables,
2291 so you can exchange any kind of data (tables, matrix, strings,…) between process via tasks.
2295 task = simgrid.Task.new("data_task",task_comp,task_comm);
2296 task['matrix'] = my_matrix;
2297 task['table'] = my_table;
2298 task['message'] = "Hello from (Lua || Simgrid ) !! "
2300 simgrid.Task.send(task,alias)
2302 After creating task, we associate to it various kind of data with a specific key (string in this case)
2303 to distinguish between data variables. The receiver will use this key to access easily to datas.
2306 \li Receiver processe
2308 task = simgrid.Task.recv(alias);
2309 sender_matrix = task['matrix'];
2310 sender_table = task['table'];
2311 sender_message = task['message']
2314 Note that in lua, both sender and receiver share the same lua task.
2315 So that the receiver could joint data directly on the received task without sending it back.
2316 You can find a complet example (matrix multiplication case) in the file example/lua/mult_matrix.lua.
2319 \subsubsection faq_binding_lua_example_bypass Bypass XML
2320 maybe you wonder if there is a way to bypass the XML files,
2321 and describe your platform directly from the code, with lua bindings it's Possible !! how ?
2322 We provide some additional (tricky?) functions in lua that allows you to set up your own platform without using the XML files
2323 ( this can be useful for large platforms, so a simple for loop will avoid you to deal with an annoying XML File ;) )
2326 \li set Routing mode
2328 simgrid.AS.new{id="AS0",mode="Full"};
2333 simgrid.Host.new{id="Tremblay",power=98095000};
2334 simgrid.Host.new{id="Jupiter",power=76296000};
2335 simgrid.Host.new{id="Fafard",power=76296000};
2336 simgrid.Host.new{id="Ginette",power=48492000};
2337 simgrid.Host.new{id="Bourassa",power=48492000};
2339 we use simgrid.Host.new{id=id_host,power=power_host} to instanciate our hosts.
2344 simgrid.Link.new{id=i,bandwidth=252750+ i*768,latency=0.000270544+i*0.087}; -- some crazy values ;)
2347 we used simgrid.Link.new{id=link_id,bandwidth=bw,latency=lat} with a simple for loop to create all links we need (much easier than XML hein ?)
2351 -- simgrid.Route.new(src_id,des_id,links_nb,links_list)
2352 simgrid.Route.new("Tremblay","Jupiter",1,{"1"});
2353 simgrid.Route.new("Tremblay","Fafard",6,{"0","1","2","3","4","8"});
2354 simgrid.Route.new("Tremblay","Ginette",3,{"3","4","5"});
2355 simgrid.Route.new("Tremblay","Bourassa",7,{"0","1","3","2","4","6","7"});
2357 simgrid.Route.new("Jupiter","Tremblay",1,{"1"});
2358 simgrid.Route.new("Jupiter","Fafard",7,{"0","1","2","3","4","8","9"});
2359 simgrid.Route.new("Jupiter","Ginette",4,{"3","4","5","9"});
2360 simgrid.Route.new("Jupiter","Bourassa",8,{"0","1","2","3","4","6","7","9"});
2363 for each host you have to specify which route to choose to access to the rest of hosts connected in the grid.
2367 simgrid.register_platform();
2369 Don't forget to register your platform, that SURF callbacks starts their work ;)
2373 simgrid.Host.setFunction("Tremblay","Master",4,{"20","550000000","1000000","4"});
2374 simgrid.Host.setFunction("Bourassa","Slave",1,{"0"});
2375 simgrid.Host.setFunction("Jupiter","Slave",1,{"1"});
2376 simgrid.Host.setFunction("Fafard","Slave",1,{"2"});
2377 simgrid.Host.setFunction("Ginette","Slave",1,{"3"});
2379 you don't need to use a deployment XML file, thanks to simgrid.Host.setFunction(host_id,function,args_number,args_list)
2380 you can associate functions for each host with arguments if needed .
2384 simgrid.register_application();
2386 Yes, Here too you have to resgiter your application before running the simulation.
2388 the full example is distributed in the file examples/lua/master_slave_bypass.lua
2390 \subsection faq_binding_ruby Ruby Binding
2393 \subsubsection faq_binding_ruby_simgrid Use Ruby in Simgrid
2394 Since v3.4, the use of <a href="http://ruby-lang.org">ruby</a> in simgrid is available for the MSG Module.
2395 you can find almost all MSG functionalities in Ruby code, that allows you to set up your environment, manage tasks between hosts and run the simulation.
2397 \dontinclude ruby/MasterSlave.rb
2398 \subsubsection faq_binding_ruby_example Master/Slave Ruby Application
2399 for each process method(master and slave in this example), you have to associate a ruby class, that should inherit from <i>MSG::Process</i> ruby class,
2400 with a 'main' function that describe the behaviour of the process during the simulation.
2408 \until end_of_master
2410 the class MSG::Task contains methods that allows the management of the native MSG tasks.
2411 in master ruby code we used :
2412 - <i>MSG::Task.new(task_name,compute_size,communication_size)</i> : to instanciate a new task.
2413 - <i>MSG::Task.send(mailbox)</i> : to send the task via a mailbox alias.
2414 - <i>MSG::Task.name</i> : to get the task's name.
2418 to receive a task, we use the method <i>MSG::Task.receive(mailbox)</i> that return a MSG:Task object (received task).
2423 - <i>MSG.createEnvironment(platform_file)</i> : set up the environment
2424 - <i>MSG.deployApplication(deployment_file)</i> : load the deployment file description.
2425 - <i>MSG.run</i> : run the simulation
2427 \subsubsection faq_binding_ruby_data Exchanging data
2428 ruby bindings provides two ways to exchange data between ruby processes.
2429 \li MSG::Task.join & MSG::Task.data \br
2431 the MSG::Task class contains 2 methods that allows a data exchange between 2 process.
2433 -<i>MSG::Task.join</i> : makes possible to join any kind of ruby data within a task.
2437 myTable <<1<<-2<<45<<67<<87<<76<<89<<56<<78<<3<<-4<<99
2438 # Creates and send Task With the Table inside
2439 task = MSG::Task.new("quicksort_task",taskComputeSize, taskCommunicationSize);
2444 -<i>MSG::Task.data</i> : to access to the data contained into the task.
2447 task = MSG::Task.receive(recv_mailbox.to_s)
2449 quicksort(table,0,table.size-1)
2452 you can find a complet example illustrating the use of those methods in file /example/ruby/Quicksort.rb
2456 another 'object-oriented' way to do it, is to make your own 'task' class that inherit from MSG::Task ,
2457 and contains data you want to deal with, the only 'tricky' thing is that "the initializer" method has no effect !
2459 the use of some getter/setter methods would be the simple way to manage your data :)
2461 class PingPongTask < MSG::Task
2462 # The initialize method has no effect
2472 you can find an example of use in file example/ruby/PingPong.rb
2474 \section faq_troubleshooting Troubleshooting
2476 \subsection faq_trouble_lib_compil SimGrid compilation and installation problems
2478 \subsubsection faq_trouble_lib_config ./configure fails!
2480 We know only one reason for the configure to fail:
2482 - <b>You are using a broken build environment</b>\n
2483 If symptom is that configure complains about gcc not being able to build
2484 executables, you are probably missing the libc6-dev package. Damn Ubuntu.
2486 If you experience other kind of issue, please get in touch with us. We are
2487 always interested in improving our portability to new systems.
2489 \subsubsection faq_trouble_distcheck Dude! "make check" fails on my machine!
2491 Don't assume we never run this target, because we do. Check
2492 http://bob.loria.fr:8010 if you don't believe us.
2494 There is several reasons which may cause the make check to fail on your
2497 - <b>You are using a broken libc (probably concerning the contextes)</b>.\n
2498 The symptom is that the "make check" fails within the examples/msg directory.\n
2499 By default, SimGrid uses something called ucontexts. This is part of the
2500 libc, but it's quite undertested. For example, some (old) versions of the
2501 glibc on alpha do not implement these functions, but provide the stubs
2502 (which return ENOSYS: not implemented). It may fool our detection mechanism
2503 and leads to segfaults. There is not much we can do to fix the bug.
2504 A workaround is to compile with --with-context=pthread to avoid
2505 ucontext completely. You'll be a bit more limited in the number
2506 of simulated processes you can start concurrently, but 5000
2507 processes is still enough for most purposes, isn't it?\n
2508 This limitation is the reason why we insist on using this piece of ...
2509 software even if it's so troublesome.\n
2510 <b>=> use --with-pthread on AMD64 architecture that do not have an
2511 ultra-recent libc.</b>
2513 - <b>There is a bug in SimGrid we aren't aware of</b>.\n
2514 If none of the above apply, please drop us a mail on the mailing list so
2515 that we can check it out. Make sure to read \ref faq_bugrepport
2518 \subsection faq_trouble_compil User code compilation problems
2520 \subsubsection faq_trouble_err_logcat "gcc: _simgrid_this_log_category_does_not_exist__??? undeclared (first use in this function)"
2522 This is because you are using the log mecanism, but you didn't created
2523 any default category in this file. You should refer to \ref XBT_log
2524 for all the details, but you simply forgot to call one of
2525 XBT_LOG_NEW_DEFAULT_CATEGORY() or XBT_LOG_NEW_DEFAULT_SUBCATEGORY().
2527 \subsubsection faq_trouble_pthreadstatic "gcc: undefined reference to pthread_key_create"
2529 This indicates that one of the library SimGrid depends on (libpthread
2530 here) was missing on the linking command line. Dependencies of
2531 libsimgrid are expressed directly in the dynamic library, so it's
2532 quite impossible that you see this message when doing dynamic linking.
2534 If you compile your code statically (and if you use a pthread version
2535 of SimGrid -- see \ref faq_more_processes), you must absolutely
2536 specify <tt>-lpthread</tt> on the linker command line. As usual, this should
2537 come after <tt>-lsimgrid</tt> on this command line.
2539 \subsection faq_trouble_errors Runtime error messages
2541 \subsubsection faq_flexml_limit "surf_parse_lex: Assertion `next limit' failed."
2543 This is because your platform file is too big for the parser.
2545 Actually, the message comes directly from FleXML, the technology on top of
2546 which the parser is built. FleXML has the bad idea of fetching the whole
2547 document in memory before parsing it. And moreover, the memory buffer size
2548 must be determined at compilation time.
2550 We use a value which seems big enough for our need without bloating the
2551 simulators footprints. But of course your mileage may vary. In this case,
2552 just edit src/surf/surfxml.l modify the definition of
2553 FLEXML_BUFFERSTACKSIZE. E.g.
2556 #define FLEXML_BUFFERSTACKSIZE 1000000000
2559 Then recompile and everything should be fine, provided that your version of
2560 Flex is recent enough (>= 2.5.31). If not the compilation process should
2563 A while ago, we worked on FleXML to reduce a bit its memory consumption, but
2564 these issues remain. There is two things we should do:
2566 - use a dynamic buffer instead of a static one so that the only limit
2567 becomes your memory, not a stupid constant fixed at compilation time
2568 (maybe not so difficult).
2569 - change the parser so that it does not need to get the whole file in
2570 memory before parsing
2571 (seems quite difficult, but I'm a complete newbe wrt flex stuff).
2573 These are changes to FleXML itself, not SimGrid. But since we kinda hijacked
2574 the development of FleXML, I can grant you that any patches would be really
2575 welcome and quickly integrated.
2577 <b>Update:</b> A new version of FleXML (1.7) was released. Most of the work
2578 was done by William Dowling, who use it in his own work. The good point is
2579 that it now use a dynamic buffer, and that the memory usage was greatly
2580 improved. The downside is that William also changed some things internally,
2581 and it breaks the hack we devised to bypass the parser, as explained in
2582 \ref faq_flexml_bypassing. Indeed, this is not a classical usage of the
2583 parser, and Will didn't imagine that we may have used (and even documented)
2584 such a crude usage of FleXML. So, we now have to repair the bypassing
2585 functionality to use the lastest FleXML version and fix the memory usage in
2588 \subsubsection faq_trouble_gras_transport GRAS spits networking error messages
2590 Gras, on real platforms, naturally use regular sockets to communicate. They
2591 are deeply hidden in the gras abstraction, but when things go wrong, you may
2592 get some weird error messages. Here are some example, with the probable
2595 - <b>Transport endpoint is not connected</b>: several processes try to open
2596 a server socket on the same port number of the same machine. This is
2597 naturally bad and each process should pick its own port number for this.\n
2598 Maybe, you just have some processes remaining from a previous experiment
2600 Killing them may help, but again if you kill -KILL them, you'll have to
2601 wait for a while: they didn't close there sockets properly and the system
2602 needs a while to notice that this port is free again.
2604 - <b>Socket closed by remote side</b>: if the remote process is not
2605 supposed to close the socket at this point, it may be dead.
2607 - <b>Connection reset by peer</b>: I found this on Internet about this
2608 error. I think it's what's happening here, too:\n
2609 <i>This basically means that a network error occurred while the client was
2610 receiving data from the server. But what is really happening is that the
2611 server actually accepts the connection, processes the request, and sends
2612 a reply to the client. However, when the server closes the socket, the
2613 client believes that the connection has been terminated abnormally
2614 because the socket implementation sends a TCP reset segment telling the
2615 client to throw away the data and report an error.\n
2616 Sometimes, this problem is caused by not properly closing the
2617 input/output streams and the socket connection. Make sure you close the
2618 input/output streams and socket connection properly. If everything is
2619 closed properly, however, and the problem persists, you can work around
2620 it by adding a one-second sleep before closing the streams and the
2621 socket. This technique, however, is not reliable and may not work on all
2623 Since GRAS sockets are closed properly (repeat after me: there is no bug
2624 in GRAS), it is either that you are closing your sockets on server side
2625 before the client get a chance to read them (use gras_os_sleep() to delay
2626 the server), or the server died awfully before the client got the data.
2628 \subsubsection faq_trouble_errors_big_fat_warning I'm told that my XML files are too old.
2630 The format of the XML platform description files is sometimes
2631 improved. For example, we decided to change the units used in SimGrid
2632 from MBytes, MFlops and seconds to Bytes, Flops and seconds to ease
2633 people exchanging small messages. We also reworked the route
2634 descriptions to allow more compact descriptions.
2636 That is why the XML files are versionned using the 'version' attribute
2637 of the root tag. Currently, it should read:
2639 <platform version="2">
2642 If your files are too old, you can use the simgrid_update_xml.pl
2643 script which can be found in the tools directory of the archive.
2645 \subsection faq_trouble_valgrind Valgrind-related and other debugger issues
2647 If you don't, you really should use valgrind to debug your code, it's
2650 \subsubsection faq_trouble_vg_longjmp longjmp madness in valgrind
2652 This is when valgrind starts complaining about longjmp things, just like:
2654 \verbatim ==21434== Conditional jump or move depends on uninitialised value(s)
2655 ==21434== at 0x420DBE5: longjmp (longjmp.c:33)
2657 ==21434== Use of uninitialised value of size 4
2658 ==21434== at 0x420DC3A: __longjmp (__longjmp.S:48)
2661 This is the sign that you didn't used the exception mecanism well. Most
2662 probably, you have a <tt>return;</tt> somewhere within a <tt>TRY{}</tt>
2663 block. This is <b>evil</b>, and you must not do this. Did you read the section
2666 \subsubsection faq_trouble_vg_libc Valgrind spits tons of errors about backtraces!
2668 It may happen that valgrind, the memory debugger beloved by any decent C
2669 programmer, spits tons of warnings like the following :
2670 \verbatim ==8414== Conditional jump or move depends on uninitialised value(s)
2671 ==8414== at 0x400882D: (within /lib/ld-2.3.6.so)
2672 ==8414== by 0x414EDE9: (within /lib/tls/i686/cmov/libc-2.3.6.so)
2673 ==8414== by 0x400B105: (within /lib/ld-2.3.6.so)
2674 ==8414== by 0x414F937: _dl_open (in /lib/tls/i686/cmov/libc-2.3.6.so)
2675 ==8414== by 0x4150F4C: (within /lib/tls/i686/cmov/libc-2.3.6.so)
2676 ==8414== by 0x400B105: (within /lib/ld-2.3.6.so)
2677 ==8414== by 0x415102D: __libc_dlopen_mode (in /lib/tls/i686/cmov/libc-2.3.6.so)
2678 ==8414== by 0x412D6B9: backtrace (in /lib/tls/i686/cmov/libc-2.3.6.so)
2679 ==8414== by 0x8076446: xbt_dictelm_get_ext (dict_elm.c:714)
2680 ==8414== by 0x80764C1: xbt_dictelm_get (dict_elm.c:732)
2681 ==8414== by 0x8079010: xbt_cfg_register (config.c:208)
2682 ==8414== by 0x806821B: MSG_config (msg_config.c:42)
2685 This problem is somewhere in the libc when using the backtraces and there is
2686 very few things we can do ourselves to fix it. Instead, here is how to tell
2687 valgrind to ignore the error. Add the following to your ~/.valgrind.supp (or
2688 create this file on need). Make sure to change the obj line according to
2689 your personnal mileage (change 2.3.6 to the actual version you are using,
2690 which you can retrieve with a simple "ls /lib/ld*.so").
2693 name: Backtrace madness
2695 obj:/lib/ld-2.3.6.so
2700 fun:__libc_dlopen_mode
2703 Then, you have to specify valgrind to use this suppression file by passing
2704 the <tt>--suppressions=$HOME/.valgrind.supp</tt> option on the command line.
2705 You can also add the following to your ~/.bashrc so that it gets passed
2706 automatically. Actually, it passes a bit more options to valgrind, and this
2707 happen to be my personnal settings. Check the valgrind documentation for
2710 \verbatim export VALGRIND_OPTS="--leak-check=yes --leak-resolution=high --num-callers=40 --tool=memcheck --suppressions=$HOME/.valgrind.supp" \endverbatim
2712 \subsubsection faq_trouble_backtraces Truncated backtraces
2714 When debugging SimGrid, it's easier to pass the
2715 --disable-compiler-optimization flag to the configure if valgrind or
2716 gdb get fooled by the optimization done by the compiler. But you
2717 should remove these flag when everything works before going in
2718 production (before launching your 1252135 experiments), or everything
2719 will run only one half of the true SimGrid potential.
2721 \subsection faq_deadlock There is a deadlock in my code!!!
2723 Unfortunately, we cannot debug every code written in SimGrid. We
2724 furthermore believe that the framework provides ways enough
2725 information to debug such informations yourself. If the textual output
2726 is not enough, Make sure to check the \ref faq_visualization FAQ entry to see
2727 how to get a graphical one.
2729 Now, if you come up with a really simple example that deadlocks and
2730 you're absolutely convinced that it should not, you can ask on the
2731 list. Just be aware that you'll be severely punished if the mistake is
2732 on your side... We have plenty of FAQ entries to redact and new
2733 features to implement for the impenitents! ;)
2735 \subsection faq_surf_network_latency I get weird timings when I play with the latencies.
2737 OK, first of all, remember that units should be Bytes, Flops and
2738 Seconds. If you don't use such units, some SimGrid constants (e.g. the
2739 SG_TCP_CTE_GAMMA constant used in most network models) won't have the
2740 right unit and you'll end up with weird results.
2742 Here is what happens with a single transfer of size L on a link
2743 (bw,lat) when nothing else happens.
2746 0-----lat--------------------------------------------------t
2747 |-----|**** real_bw =min(bw,SG_TCP_CTE_GAMMA/(2*lat)) *****|
2750 In more complex situations, this min is the solution of a complex
2751 max-min linear system. Have a look
2752 <a href="http://lists.gforge.inria.fr/pipermail/simgrid-devel/2006-April/thread.html">here</a>
2753 and read the two threads "Bug in SURF?" and "Surf bug not
2754 fixed?". You'll have a few other examples of such computations. You
2755 can also read "A Network Model for Simulation of Grid Application" by
2756 Henri Casanova and Loris Marchal to have all the details. The fact
2757 that the real_bw is smaller than bw is easy to understand. The fact
2758 that real_bw is smaller than SG_TCP_CTE_GAMMA/(2*lat) is due to the
2759 window-based congestion mechanism of TCP. With TCP, you can't exploit
2760 your huge network capacity if you don't have a good round-trip-time
2761 because of the acks...
2763 Anyway, what you get is t=lat + L/min(bw,SG_TCP_CTE_GAMMA/(2*lat)).
2765 * if I you set (bw,lat)=(100 000 000, 0.00001), you get t = 1.00001 (you fully
2767 * if I you set (bw,lat)=(100 000 000, 0.0001), you get t = 1.0001 (you're on the
2769 * if I you set (bw,lat)=(100 000 000, 0.001), you get t = 10.001 (ouch!)
2771 This bound on the effective bandwidth of a flow is not the only thing
2772 that may make your result be unexpected. For example, two flows
2773 competing on a saturated link receive an amount of bandwidth inversely
2774 proportional to their round trip time.
2776 \subsection faq_bugrepport So I've found a bug in SimGrid. How to report it?
2778 We do our best to make sure to hammer away any bugs of SimGrid, but this is
2779 still an academic project so please be patient if/when you find bugs in it.
2780 If you do, the best solution is to drop an email either on the simgrid-user
2781 or the simgrid-devel mailing list and explain us about the issue. You can
2782 also decide to open a formal bug report using the
2783 <a href="https://gforge.inria.fr/tracker/?atid=165&group_id=12&func=browse">relevant
2784 interface</a>. You need to login on the server to get the ability to submit
2787 We will do our best to solve any problem repported, but you need to help us
2788 finding the issue. Just telling "it segfault" isn't enough. Telling "It
2789 segfaults when running the attached simulator" doesn't really help either.
2790 You may find the following article interesting to see how to repport
2791 informative bug repports:
2792 http://www.chiark.greenend.org.uk/~sgtatham/bugs.html (it is not SimGrid
2793 specific at all, but it's full of good advices).
2795 \author Arnaud Legrand (arnaud.legrand::imag.fr)
2796 \author Martin Quinson (martin.quinson::loria.fr)
2801 ******************************************************************
2802 * OLD CRUFT NOT USED ANYMORE *
2803 ******************************************************************
2806 \subsection faq_crosscompile Cross-compiling a Windows DLL of SimGrid from linux
2808 At the moment, we do not distribute Windows pre-compiled version of SimGrid
2809 because the support for this platform is still experimental. We know that
2810 some parts of the GRAS environment do not work, and we think that the others
2811 environments (MSG and SD) have good chances to work, but we didn't test
2812 ourselves. This section explains how we generate the SimGrid DLL so that you
2813 can build it for yourself. First of all, you need to have a version more
2814 recent than 3.1 (ie, a SVN version as time of writting).
2816 In order to cross-compile the package to windows from linux, you need to
2817 install mingw32 (minimalist gnu win32). On Debian, you can do so by
2818 installing the packages mingw32 (compiler), mingw32-binutils (linker and
2819 so), mingw32-runtime.
2821 You can use the VPATH support of configure to compile at the same time for
2822 linux and windows without dupplicating the source nor cleaning the tree
2823 between each. Just run bootstrap (if you use the SVN) to run the autotools.
2824 Then, create a linux and a win directories. Then, type:
2825 \verbatim cd linux; ../configure --srcdir=.. <usual configure flags>; make; cd ..
2826 cd win; ../configure --srcdir=.. --host=i586-mingw32msvc <flags>; make; cd ..
2828 The trick to VPATH builds is to call configure from another directory,
2829 passing it an extra --srcdir argument to tell it where all the sources are.
2830 It will understand you want to use VPATH. Then, the trick to cross-compile
2831 is simply to add a --host argument specifying the target you want to build
2832 for. The i586-mingw32msvc string is what you have to pass to use the mingw32
2833 environment as distributed in Debian.
2835 After that, you can run all make targets from both directories, and test
2836 easily that what you change for one arch does not break the other one.
2838 It is possible that this VPATH build thing breaks from time to time in the
2839 SVN since it's quite fragile, but it's granted to work in any released
2840 version. If you experience problems, drop us a mail.
2842 Another possible source of issue is that at the moment, building the
2843 examples request to use the gras_stub_generator tool, which is a compiled
2844 program, not a script. In cross-compilation, you need to cross-execute with
2845 wine for example, which is not really pleasant. We are working on this, but
2846 in the meanwhile, simply don't build the examples in cross-compilation
2847 (<tt>cd src</tt> before running make).
2849 Program (cross-)compiled with mingw32 do request an extra DLL at run-time to be
2850 usable. For example, if you want to test your build with wine, you should do
2851 the following to put this library where wine looks for DLLs.
2853 cp /usr/share/doc/mingw32-runtime/mingwm10.dll.gz ~/.wine/c/windows/system/
2854 gunzip ~/.wine/c/windows/system/mingwm10.dll.gz
2857 The DLL is built in src/.libs, and installed in the <i>prefix</i>/bin directory
2858 when you run make install.
2860 If you want to use it in a native project on windows, you need to use
2861 simgrid.dll and mingwm10.dll. For each DLL, you need to build .def file
2862 under linux (listing the defined symbols), and convert it into a .lib file
2863 under windows (specifying this in a way that windows compilers like). To
2864 generate the def files, run (under linux):
2865 \verbatim echo "LIBRARY libsimgrid-0.dll" > simgrid.def
2866 echo EXPORTS >> simgrid.def
2867 nm libsimgrid-0.dll | grep ' T _' | sed 's/.* T _//' >> simgrid.def
2868 nm libsimgrid-0.dll | grep ' D _' | sed 's/.* D _//' | sed 's/$/ DATA/' >> simgrid.def
2870 echo "LIBRARY mingwm10.dll" > mingwm10.def
2871 echo EXPORTS >> mingwm10.def
2872 nm mingwm10.dll | grep ' T _' | sed 's/.* T _//' >> mingwm10.def
2873 nm mingwm10.dll | grep ' D _' | sed 's/.* D _//' | sed 's/$/ DATA/' >> mingwm10.def
2876 To create the import .lib files, use the <tt>lib</tt> windows tool (from
2877 MSVC) the following way to produce simgrid.lib and mingwm10.lib
2878 \verbatim lib /def:simgrid.def
2879 lib /def:mingwm10.def
2882 If you happen to use Borland C Builder, the right command line is the
2883 following (note that you don't need any file.def to get this working).
2884 \verbatim implib simgrid.lib libsimgrid-0.dll
2885 implib mingwm10.lib mingwm10.dll
2888 Then, set the following parameters in Visual C++ 2005:
2889 Linker -> Input -> Additional dependencies = simgrid.lib mingwm10.lib
2891 Just in case you wonder how to generate a DLL from libtool in another
2892 project, we added -no-undefined to any lib*_la_LDFLAGS variables so that
2893 libtool accepts to generate a dynamic library under windows. Then, to make
2894 it true, we pass any dependencies (such as -lws2 under windows or -lpthread
2895 on need) on the linking line. Passing such deps is a good idea anyway so
2896 that they get noted in the library itself, avoiding the users to know about
2897 our dependencies and put them manually on their compilation line. Then we
2898 added the AC_LIBTOOL_WIN32_DLL macro just before AC_PROG_LIBTOOL in the
2899 configure.ac. It means that we exported any symbols which need to be.
2900 Nowadays, functions get automatically exported, so we don't need to load our
2901 header files with tons of __declspec(dllexport) cruft. We only need to do so
2902 for data, but there is no public data in SimGrid so we are good.