/* StarPU --- Runtime system for heterogeneous multicore architectures. * * Copyright (C) 2009-2021 Université de Bordeaux, CNRS (LaBRI UMR 5800), Inria * Copyright (C) 2020 Federal University of Rio Grande do Sul (UFRGS) * * StarPU is free software; you can redistribute it and/or modify * it under the terms of the GNU Lesser General Public License as published by * the Free Software Foundation; either version 2.1 of the License, or (at * your option) any later version. * * StarPU is distributed in the hope that it will be useful, but * WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. * * See the GNU Lesser General Public License in COPYING.LGPL for more details. */ /*! \page OfflinePerformanceTools Offline Performance Tools To get an idea of what is happening, a lot of performance feedback is available, detailed in this chapter. The various informations should be checked for. You can also use the Temanejo task debugger (see \ref UsingTheTemanejoTaskDebugger) to visualize the task graph more easily. \section Off-linePerformanceFeedback Off-line Performance Feedback \subsection GeneratingTracesWithFxT Generating Traces With FxT StarPU can use the FxT library (see https://savannah.nongnu.org/projects/fkt/) to generate traces with a limited runtime overhead. You can get a tarball from http://download.savannah.gnu.org/releases/fkt/?C=M Compiling and installing the FxT library in the $FXTDIR path is done following the standard procedure: \verbatim $ ./configure --prefix=$FXTDIR $ make $ make install \endverbatim In order to have StarPU to generate traces, StarPU needs be configured again after installing FxT, and configuration show: \verbatim FxT trace enabled: yes \endverbatim If configure does not find FxT automatically, it can be specified by hand with the option \ref with-fxt "--with-fxt" : \verbatim $ ./configure --with-fxt=$FXTDIR \endverbatim Or you can simply point the PKG_CONFIG_PATH to $FXTDIR/lib/pkgconfig When \ref STARPU_FXT_TRACE is set to 1, a trace is generated when StarPU is terminated by calling starpu_shutdown(). The trace is a binary file whose name has the form prof_file_XXX_YYY where XXX is the user name, and YYY is the MPI id of the process that used StarPU (or 0 when running a sequential program). One can change the name of the file by setting the environnement variable \ref STARPU_FXT_SUFFIX, its contents will be used instead of prof_file_XXX. This file is saved in the /tmp/ directory by default, or by the directory specified by the environment variable \ref STARPU_FXT_PREFIX. The additional \c configure option \ref enable-fxt-lock "--enable-fxt-lock" can be used to generate trace events which describes the locks behaviour during the execution. It is however very heavy and should not be used unless debugging StarPU's internal locking. When the FxT trace file prof_file_something has been generated, it is possible to generate different trace formats by calling: \verbatim $ starpu_fxt_tool -i /tmp/prof_file_something \endverbatim Or alternatively, setting the environment variable \ref STARPU_GENERATE_TRACE to 1 before application execution will make StarPU automatically generate all traces at application shutdown. Note that if the environment variable \ref STARPU_FXT_PREFIX is set, files will be generated in the given directory. One can also set the environment variable \ref STARPU_GENERATE_TRACE_OPTIONS to specify options, see starpu_fxt_tool --help, for example: \verbatim $ export STARPU_GENERATE_TRACE=1 $ export STARPU_GENERATE_TRACE_OPTIONS="-no-acquire" \endverbatim When running a MPI application, \ref STARPU_GENERATE_TRACE will not work as expected (each node will try to generate trace files, thus mixing outputs...), you have to collect the trace files from the MPI nodes, and specify them all on the command starpu_fxt_tool, for instance: \verbatim $ starpu_fxt_tool -i /tmp/prof_file_something* \endverbatim By default, the generated trace contains all informations. To reduce the trace size, various -no-foo options can be passed to starpu_fxt_tool, see starpu_fxt_tool --help . \subsubsection CreatingAGanttDiagram Creating a Gantt Diagram One of the generated files is a trace in the Paje format. The file, located in the current directory, is named paje.trace. It can be viewed with ViTE (http://vite.gforge.inria.fr/) a trace visualizing open-source tool. To open the file paje.trace with ViTE, use the following command: \verbatim $ vite paje.trace \endverbatim Tasks can be assigned a name (instead of the default \c unknown) by filling the optional starpu_codelet::name, or assigning them a performance model. The name can also be set with the field starpu_task::name or by using \ref STARPU_NAME when calling starpu_task_insert(). Tasks are assigned default colors based on the worker which executed them (green for CPUs, yellow/orange/red for CUDAs, blue for OpenCLs, ...). To use a different color for every type of task, one can specify the option -c to starpu_fxt_tool or in \ref STARPU_GENERATE_TRACE_OPTIONS. Tasks can also be given a specific color by setting the field starpu_codelet::color or the starpu_task::color. Colors are expressed with the following format \c 0xRRGGBB (e.g \c 0xFF0000 for red). See basic_examples/task_insert_color for examples on how to assign colors. To get statistics on the time spend in runtime overhead, one can use the statistics plugin of ViTE. In Preferences, select Plugins. In "States Type", select "Worker State". Then click on "Reload" to update the histogram. The red "Idle" percentages are due to lack of parallelism, while the brown "Overhead" and "Scheduling" percentages are due to the overhead of the runtime and of the scheduler. To identify tasks precisely, the application can also set the field starpu_task::tag_id or setting \ref STARPU_TAG_ONLY when calling starpu_task_insert(). The value of the tag will then show up in the trace. One can also introduce user-defined events in the diagram thanks to the starpu_fxt_trace_user_event_string() function. One can also set the iteration number, by just calling starpu_iteration_push() at the beginning of submission loops and starpu_iteration_pop() at the end of submission loops. These iteration numbers will show up in traces for all tasks submitted from there. Coordinates can also be given to data with the starpu_data_set_coordinates() or starpu_data_set_coordinates_array() function. In the trace, tasks will then be assigned the coordinates of the first data they write to. Traces can also be inspected by hand by using the tool fxt_print, for instance: \verbatim $ fxt_print -o -f /tmp/prof_file_something \endverbatim Timings are in nanoseconds (while timings as seen in ViTE are in milliseconds). \subsubsection CreatingADAGWithGraphviz Creating a DAG With Graphviz Another generated trace file is a task graph described using the DOT language. The file, created in the current directory, is named dag.dot file in the current directory. It is possible to get a graphical output of the graph by using the graphviz library: \verbatim $ dot -Tpdf dag.dot -o output.pdf \endverbatim \subsubsection TraceTaskDetails Getting Task Details Another generated trace file gives details on the executed tasks. The file, created in the current directory, is named tasks.rec. This file is in the recutils format, i.e. Field: value lines, and empty lines are used to separate each task. This can be used as a convenient input for various ad-hoc analysis tools. By default it only contains information about the actual execution. Performance models can be obtained by running starpu_tasks_rec_complete on it: \verbatim $ starpu_tasks_rec_complete tasks.rec tasks2.rec \endverbatim which will add EstimatedTime lines which contain the performance model-estimated time (in µs) for each worker starting from 0. Since it needs the performance models, it needs to be run the same way as the application execution, or at least with STARPU_HOSTNAME set to the hostname of the machine used for execution, to get the performance models of that machine. Another possibility is to obtain the performance models as an auxiliary perfmodel.rec file, by using the starpu_perfmodel_recdump utility: \verbatim $ starpu_perfmodel_recdump tasks.rec -o perfmodel.rec \endverbatim \subsubsection TraceSchedTaskDetails Getting Scheduling Task Details The file, sched_tasks.rec, created in the current directory, and in the recutils format, gives information about the tasks scheduling, and lists the push and pop actions of the scheduler. For each action, it gives the timestamp, the job priority and the job id. Each action is separated from the next one by empty lines. \subsubsection MonitoringActivity Monitoring Activity Another generated trace file is an activity trace. The file, created in the current directory, is named activity.data. A profile of the application showing the activity of StarPU during the execution of the program can be generated: \verbatim $ starpu_workers_activity activity.data \endverbatim This will create a file named activity.eps in the current directory. This picture is composed of two parts. The first part shows the activity of the different workers. The green sections indicate which proportion of the time was spent executed kernels on the processing unit. The red sections indicate the proportion of time spent in StartPU: an important overhead may indicate that the granularity may be too low, and that bigger tasks may be appropriate to use the processing unit more efficiently. The black sections indicate that the processing unit was blocked because there was no task to process: this may indicate a lack of parallelism which may be alleviated by creating more tasks when it is possible. The second part of the picture activity.eps is a graph showing the evolution of the number of tasks available in the system during the execution. Ready tasks are shown in black, and tasks that are submitted but not schedulable yet are shown in grey. \subsubsection Animation Getting Modular Schedular Animation When using modular schedulers (i.e. schedulers which use a modular architecture, and whose name start with "modular-"), the call to starpu_fxt_tool will also produce a trace.html file which can be viewed in a javascript-enabled web browser. It shows the flow of tasks between the components of the modular scheduler. \subsubsection TimeBetweenSendRecvDataUse Analyzing Time Between MPI Data Transfer and Use by Tasks starpu_fxt_tool produces a file called comms.rec which describes all MPI communications. The script starpu_send_recv_data_use.py uses this file and tasks.rec in order to produce two graphs: the first one shows durations between the reception of data and their usage by a task and the second one plots the same graph but with elapsed time between send and usage of a data by the sender. \image html trace_recv_use.png \image latex trace_recv_use.eps "" width=\textwidth \image html trace_send_use.png \image latex trace_send_use.eps "" width=\textwidth \subsubsection NumberEvents Number of events in trace files When launched with the option -number-events, starpu_fxt_tool will produce a file named number_events.data. This file contains the number of events for each event type. Events are represented with their key. To convert event keys to event names, you can use the starpu_fxt_number_events_to_names.py script: \verbatim $ starpu_fxt_number_events_to_names.py number_events.data \endverbatim \subsection LimitingScopeTrace Limiting The Scope Of The Trace For computing statistics, it is useful to limit the trace to a given portion of the time of the whole execution. This can be achieved by calling \code{.c} starpu_fxt_autostart_profiling(0) \endcode before calling starpu_init(), to prevent tracing from starting immediately. Then \code{.c} starpu_fxt_start_profiling(); \endcode and \code{.c} starpu_fxt_stop_profiling(); \endcode can be used around the portion of code to be traced. This will show up as marks in the trace, and states of workers will only show up for that portion. \section PerformanceOfCodelets Performance Of Codelets The performance model of codelets (see \ref PerformanceModelExample) can be examined by using the tool starpu_perfmodel_display: \verbatim $ starpu_perfmodel_display -l file: file: file: file: file: \endverbatim Here, the codelets of the example lu are available. We can examine the performance of the kernel 22 (in micro-seconds), which is history-based: \verbatim $ starpu_perfmodel_display -s starpu_slu_lu_model_22 performance model for cpu # hash size mean dev n 57618ab0 19660800 2.851069e+05 1.829369e+04 109 performance model for cuda_0 # hash size mean dev n 57618ab0 19660800 1.164144e+04 1.556094e+01 315 performance model for cuda_1 # hash size mean dev n 57618ab0 19660800 1.164271e+04 1.330628e+01 360 performance model for cuda_2 # hash size mean dev n 57618ab0 19660800 1.166730e+04 3.390395e+02 456 \endverbatim We can see that for the given size, over a sample of a few hundreds of execution, the GPUs are about 20 times faster than the CPUs (numbers are in us). The standard deviation is extremely low for the GPUs, and less than 10% for CPUs. This tool can also be used for regression-based performance models. It will then display the regression formula, and in the case of non-linear regression, the same performance log as for history-based performance models: \verbatim $ starpu_perfmodel_display -s non_linear_memset_regression_based performance model for cpu_impl_0 Regression : #sample = 1400 Linear: y = alpha size ^ beta alpha = 1.335973e-03 beta = 8.024020e-01 Non-Linear: y = a size ^b + c a = 5.429195e-04 b = 8.654899e-01 c = 9.009313e-01 # hash size mean stddev n a3d3725e 4096 4.763200e+00 7.650928e-01 100 870a30aa 8192 1.827970e+00 2.037181e-01 100 48e988e9 16384 2.652800e+00 1.876459e-01 100 961e65d2 32768 4.255530e+00 3.518025e-01 100 ... \endverbatim The same can also be achieved by using StarPU's library API, see \ref API_Performance_Model and notably the function starpu_perfmodel_load_symbol(). The source code of the tool starpu_perfmodel_display can be a useful example. An XML output can also be printed by using the -x option: \verbatim $ tools/starpu_perfmodel_display -x -s non_linear_memset_regression_based \endverbatim The tool starpu_perfmodel_plot can be used to draw performance models. It writes a .gp file in the current directory, to be run with the tool gnuplot, which shows the corresponding curve. \verbatim $ tools/starpu_perfmodel_plot -s non_linear_memset_regression_based $ gnuplot starpu_non_linear_memset_regression_based.gp $ gv starpu_non_linear_memset_regression_based.eps \endverbatim \image html starpu_non_linear_memset_regression_based.png \image latex starpu_non_linear_memset_regression_based.eps "" width=\textwidth When the field starpu_task::flops is set (or \ref STARPU_FLOPS is passed to starpu_task_insert()), starpu_perfmodel_plot can directly draw a GFlops curve, by simply adding the -f option: \verbatim $ starpu_perfmodel_plot -f -s chol_model_11 \endverbatim This will however disable displaying the regression model, for which we can not compute GFlops. \image html starpu_chol_model_11_type.png \image latex starpu_chol_model_11_type.eps "" width=\textwidth When the FxT trace file prof_file_something has been generated, it is possible to get a profiling of each codelet by calling: \verbatim $ starpu_fxt_tool -i /tmp/prof_file_something $ starpu_codelet_profile distrib.data codelet_name \endverbatim This will create profiling data files, and a distrib.data.gp file in the current directory, which draws the distribution of codelet time over the application execution, according to data input size. \image html distrib_data.png \image latex distrib_data.eps "" width=\textwidth This is also available in the tool starpu_perfmodel_plot, by passing it the fxt trace: \verbatim $ starpu_perfmodel_plot -s non_linear_memset_regression_based -i /tmp/prof_file_foo_0 \endverbatim It will produce a .gp file which contains both the performance model curves, and the profiling measurements. \image html starpu_non_linear_memset_regression_based_2.png \image latex starpu_non_linear_memset_regression_based_2.eps "" width=\textwidth If you have the statistical tool R installed, you can additionally use \verbatim $ starpu_codelet_histo_profile distrib.data \endverbatim Which will create one .pdf file per codelet and per input size, showing a histogram of the codelet execution time distribution. \image html distrib_data_histo.png \image latex distrib_data_histo.eps "" width=\textwidth \section EnergyOfCodelets Energy Of Codelets A performance model of the energy of codelets can also be recorded thanks to the starpu_codelet::energy_model field of the starpu_codelet structure. StarPU usually cannot record this automatically since the energy measurement probes are usually not fine-grain enough. It is however possible to measure it by writing a program that submits batches of tasks, let StarPU measure the energy requirement of the batch, and compute an average, see \ref MeasuringEnergyandPower . The energy performance model can then be displayed in Joules with starpu_perfmodel_display just like the time performance model. The starpu_perfmodel_plot needs an extra -e option to display the proper unit in the graph: \verbatim $ tools/starpu_perfmodel_plot -e -s non_linear_memset_regression_based_energy $ gnuplot starpu_non_linear_memset_regression_based_energy.gp $ gv starpu_non_linear_memset_regression_based_energy.eps \endverbatim \image html starpu_non_linear_memset_regression_based_energy.png \image latex starpu_non_linear_memset_regression_based_energy.eps "" width=\textwidth The -f option can also be used to display the performance in terms of GFlop/s/W, i.e. the efficiency: \verbatim $ tools/starpu_perfmodel_plot -f -e -s non_linear_memset_regression_based_energy $ gnuplot starpu_gflops_non_linear_memset_regression_based_energy.gp $ gv starpu_gflops_non_linear_memset_regression_based_energy.eps \endverbatim \image html starpu_gflops_non_linear_memset_regression_based_energy.png \image latex starpu_gflops_non_linear_memset_regression_based_energy.eps "" width=\textwidth We clearly see here that it is much more energy-efficient to stay in the L3 cache. One can combine the two time and energy performance models to draw Watts: \verbatim $ tools/starpu_perfmodel_plot -se non_linear_memset_regression_based non_linear_memset_regression_based_energy $ gnuplot starpu_power_non_linear_memset_regression_based.gp $ gv starpu_power_non_linear_memset_regression_based.eps \endverbatim \image html starpu_power_non_linear_memset_regression_based.png \image latex starpu_power_non_linear_memset_regression_based.eps "" width=\textwidth \section DataTrace Data trace and tasks length It is possible to get statistics about tasks length and data size by using : \verbatim $ starpu_fxt_data_trace filename [codelet1 codelet2 ... codeletn] \endverbatim Where filename is the FxT trace file and codeletX the names of the codelets you want to profile (if no names are specified, starpu_fxt_data_trace will profile them all). This will create a file, data_trace.gp which can be executed to get a .eps image of these results. On the image, each point represents a task, and each color corresponds to a codelet. \image html data_trace.png \image latex data_trace.eps "" width=\textwidth \section TraceStatistics Trace Statistics More than just codelet performance, it is interesting to get statistics over all kinds of StarPU states (allocations, data transfers, etc.). This is particularly useful to check what may have gone wrong in the accurracy of the SimGrid simulation. This requires the R statistical tool, with the plyr, ggplot2 and data.table packages. If your system distribution does not have packages for these, one can fetch them from CRAN: \verbatim $ R > install.packages("plyr") > install.packages("ggplot2") > install.packages("data.table") > install.packages("knitr") \endverbatim The pj_dump tool from pajeng is also needed (see https://github.com/schnorr/pajeng) One can then get textual or .csv statistics over the trace states: \verbatim $ starpu_paje_state_stats -v native.trace simgrid.trace "Value" "Events_native.csv" "Duration_native.csv" "Events_simgrid.csv" "Duration_simgrid.csv" "Callback" 220 0.075978 220 0 "chol_model_11" 10 565.176 10 572.8695 "chol_model_21" 45 9184.828 45 9170.719 "chol_model_22" 165 64712.07 165 64299.203 $ starpu_paje_state_stats native.trace simgrid.trace \endverbatim An other way to get statistics of StarPU states (without installing R and pj_dump) is to use the starpu_trace_state_stats.py script which parses the generated trace.rec file instead of the paje.trace file. The output is similar to the previous script but it doesn't need any dependencies. The different prefixes used in trace.rec are: \verbatim E: Event type N: Event name C: Event category W: Worker ID T: Thread ID S: Start time \endverbatim Here's an example on how to use it: \verbatim $ starpu_trace_state_stats.py trace.rec | column -t -s "," "Name" "Count" "Type" "Duration" "Callback" 220 Runtime 0.075978 "chol_model_11" 10 Task 565.176 "chol_model_21" 45 Task 9184.828 "chol_model_22" 165 Task 64712.07 \endverbatim starpu_trace_state_stats.py can also be used to compute the different efficiencies. Refer to the usage description to show some examples. And one can plot histograms of execution times, of several states for instance: \verbatim $ starpu_paje_draw_histogram -n chol_model_11,chol_model_21,chol_model_22 native.trace simgrid.trace \endverbatim and see the resulting pdf file: \image html paje_draw_histogram.png \image latex paje_draw_histogram.eps "" width=\textwidth A quick statistical report can be generated by using: \verbatim $ starpu_paje_summary native.trace simgrid.trace \endverbatim it includes gantt charts, execution summaries, as well as state duration charts and time distribution histograms. Other external Paje analysis tools can be used on these traces, one just needs to sort the traces by timestamp order (which not guaranteed to make recording more efficient): \verbatim $ starpu_paje_sort paje.trace \endverbatim \section PapiCounters PAPI counters Performance counter values could be obtained from the PAPI framework if ./configure detected the libpapi. In Debian, packages libpapi-dev and libpapi5.7 provide required files. Package papi-tools contains a set of useful tools, for example papi_avail to see which counters are available. To be able to use Papi counters, one may need to reduce the level of the kernel parameter kernel.perf_event_paranoid to at least 2. See https://www.kernel.org/doc/html/latest/admin-guide/perf-security.html for the security impact of this parameter. Then one has to set the \ref STARPU_PROFILING environment variable to 1 and specify which events to record with the \ref STARPU_PROF_PAPI_EVENTS environment variable. For instance: \verbatim export STARPU_PROFILING=1 STARPU_PROF_PAPI_EVENTS="PAPI_TOT_INS PAPI_TOT_CYC" \endverbatim The comma can also be used to separate events to monitor. In the current simple implementation, only CPU tasks have their events measured and require CPUs that support the PAPI events. It is important to note that not all events are available on all systems, and general PAPI recommendations should be followed. The counter values can be accessed using the profiling interface: \code{.c} task->profiling_info->papi_values \endcode Also, it can be accessed and/or saved with tracing when using \ref STARPU_FXT_TRACE. With the use of starpu_fxt_tool the file papi.rec is generated containing the following triple: \verbatim Task Id Event Id Value \endverbatim External tools like rec2csv can be used to convert this rec file to a csv, where each line represents a value for an event for a task. \section TheoreticalLowerBoundOnExecutionTime Theoretical Lower Bound On Execution Time StarPU can record a trace of what tasks are needed to complete the application, and then, by using a linear system, provide a theoretical lower bound of the execution time (i.e. with an ideal scheduling). The computed bound is not really correct when not taking into account dependencies, but for an application which have enough parallelism, it is very near to the bound computed with dependencies enabled (which takes a huge lot more time to compute), and thus provides a good-enough estimation of the ideal execution time. \ref TheoreticalLowerBoundOnExecutionTimeExample provides an example on how to use this. \section TheoreticalLowerBoundOnExecutionTimeExample Theoretical Lower Bound On Execution Time Example For kernels with history-based performance models (and provided that they are completely calibrated), StarPU can very easily provide a theoretical lower bound for the execution time of a whole set of tasks. See for instance examples/lu/lu_example.c: before submitting tasks, call the function starpu_bound_start(), and after complete execution, call starpu_bound_stop(). starpu_bound_print_lp() or starpu_bound_print_mps() can then be used to output a Linear Programming problem corresponding to the schedule of your tasks. Run it through lp_solve or any other linear programming solver, and that will give you a lower bound for the total execution time of your tasks. If StarPU was compiled with the library glpk installed, starpu_bound_compute() can be used to solve it immediately and get the optimized minimum, in ms. Its parameter integer allows to decide whether integer resolution should be computed and returned The deps parameter tells StarPU whether to take tasks, implicit data, and tag dependencies into account. Tags released in a callback or similar are not taken into account, only tags associated with a task are. It must be understood that the linear programming problem size is quadratic with the number of tasks and thus the time to solve it will be very long, it could be minutes for just a few dozen tasks. You should probably use lp_solve -timeout 1 test.pl -wmps test.mps to convert the problem to MPS format and then use a better solver, glpsol might be better than lp_solve for instance (the --pcost option may be useful), but sometimes doesn't manage to converge. cbc might look slower, but it is parallel. For lp_solve, be sure to try at least all the -B options. For instance, we often just use lp_solve -cc -B1 -Bb -Bg -Bp -Bf -Br -BG -Bd -Bs -BB -Bo -Bc -Bi , and the -gr option can also be quite useful. The resulting schedule can be observed by using the tool starpu_lp2paje, which converts it into the Paje format. Data transfer time can only be taken into account when deps is set. Only data transfers inferred from implicit data dependencies between tasks are taken into account. Other data transfers are assumed to be completely overlapped. Setting deps to 0 will only take into account the actual computations on processing units. It however still properly takes into account the varying performances of kernels and processing units, which is quite more accurate than just comparing StarPU performances with the fastest of the kernels being used. The prio parameter tells StarPU whether to simulate taking into account the priorities as the StarPU scheduler would, i.e. schedule prioritized tasks before less prioritized tasks, to check to which extend this results to a less optimal solution. This increases even more computation time. \section starvz Trace visualization with StarVZ Creating views with StarVZ (see: https://github.com/schnorr/starvz) is made up of two steps. The initial stage consists of a pre-processing of the traces generated by the application, while the second one consists of the analysis itself and is carried out with R packages' aid. StarVZ is available at CRAN (https://cran.r-project.org/package=starvz) and depends on pj_dump (from pajeng) and rec2csv (from recutils). To download and install StarVZ, it is necessary to have R, pajeng, and recutils: \verbatim # For pj_dump and rec2csv apt install -y pajeng recutils # For R apt install -y r-base libxml2-dev libssl-dev libcurl4-openssl-dev libgit2-dev libboost-dev \endverbatim To install the StarVZ, the following command can be used: \verbatim echo "install.packages('starvz', repos = 'https://cloud.r-project.org')" | R --vanilla \endverbatim To generate traces from an application, it is necessary to set \ref STARPU_GENERATE_TRACE and build StarPU with FxT. Then, StarVZ can be used on a folder with StarPU FxT traces to produce a default view: \verbatim export PATH=$(Rscript -e 'cat(system.file("tools/", package = "starvz"), sep="\n")'):$PATH starvz /foo/path-to-fxt-files \endverbatim An example of default view: \image html starvz_visu.png \image latex starvz_visu.pdf "" width=\textwidth One can also use existing trace files (paje.trace, tasks.rec, data.rec, papi.rec and dag.dot) skipping the StarVZ internal call to starpu_fxt_tool with: \verbatim starvz --use-paje-trace /foo/path-to-trace-files \endverbatim Alternatively, each StarVZ step can be executed separately. Step 1 can be used on a folder with: \verbatim starvz -1 /foo/path-to-fxt-files \endverbatim Then the second step can be executed directly in R. StarVZ enables a set of different plots that can be configured on a .yaml file. A default file is provided (default.yaml); also, the options can be changed directly in R. \verbatim library(starvz) library(dplyr) dtrace <- starvz_read("./", selective = FALSE) # show idleness ratio dtrace$config$st$idleness = TRUE # show ABE bound dtrace$config$st$abe$active = TRUE # find the last task with dplyr dtrace$config$st$tasks$list = dtrace$Application %>% filter(End == max(End)) %>% .$JobId # show last task dependencies dtrace$config$st$tasks$active = TRUE dtrace$config$st$tasks$levels = 50 plot <- starvz_plot(dtrace) \endverbatim An example of visualization follows: \image html starvz_visu_r.png \image latex starvz_visu_r.pdf "" width=\textwidth \section EclipsePluginUsage StarPU Eclipse Plugin The StarPU Eclipse Plugin provides the ability to generate the different traces directly from the Eclipse IDE. Once StarPU has been configured and installed with its Eclipse plugin (see Section \ref EclipsePlugin), you first need to set up your environment for StarPU. \verbatim cd $HOME/usr/local/starpu source ./bin/starpu_env \endverbatim To generate traces from the application, it is necessary to set \ref STARPU_FXT_TRACE to 1. \verbatim export STARPU_FXT_TRACE=1 \endverbatim The eclipse workspace together with an example is available in \c lib/starpu/eclipse-plugin. \verbatim cd ./lib/starpu/eclipse-plugin eclipse -data workspace \endverbatim You can then open the file \c hello/hello.c, and build the application by pressing \c Ctrl-B. \image html eclipse_hello_build.png \image latex eclipse_hello_build.png "" width=\textwidth The application can now be executed. \image html eclipse_hello_run.png \image latex eclipse_hello_run.png "" width=\textwidth After executing the C/C++ StarPU application, one can use the StarPU plugin to generate and visualise the task graph of the application. The StarPU plugin eclipse is either available through the icons in the upper toolbar, or from the dropdown menu \c StarPU. \image html eclipse_plugin.png \image latex eclipse_plugin.png "" width=\textwidth To start, one first need to run the StarPU FxT tool, either through the \c FxT icon of the toolbar, or from the menu \c StarPU / StarPU FxT Tool. This will call the tool \c starpu_fxt_tool to generate traces for your application execution. A message dialog box is displayed to confirm the generation of the different traces. \image html eclipse_hello_fxt.png \image latex eclipse_hello_fxt.png "" width=\textwidth One of the generated files is a Paje trace which can be viewed with ViTE, a trace explorer. To open and visualise the file \c paje.trace with ViTE, one can select the second command of the StarPU menu, which is named Generate Paje Trace, or click on the second icon named Trace in the toolbar. \image html eclipse_paje_trace.png \image latex eclipse_paje_trace.png "" width=\textwidth \image html eclipse_vite.png \image latex eclipse_vite.png "" width=\textwidth Another generated trace file is a task graph described using the DOT language. It is possible to get a graphical output of the graph by calling the graphviz library. To do this, one can click on the third command of StarPU menu. A task graph of the application in the \c png format is then generated. \image html eclipse_hello_graph.png \image latex eclipse_hello_graph.png "" width=\textwidth In StarPU eclipse plugin, one can display the graph task directly from eclipse, or through a web browser. To do this, there is another command named Generate SVG graph in the StarPU menu or HGraph in the toolbar of eclipse. From the HTML file, you can see the graph task, and by clicking on a task name, it will open the C file in which the task submission was called (if you have an editor which understands the syntax \c href="file.c#123"). \image html eclipse_svg_graph.png \image latex eclipse_svg_graph.png "" width=\textwidth \image html eclipse_hgraph.png \image latex eclipse_hgraph.png "" width=\textwidth \section MemoryFeedback Memory Feedback It is possible to enable memory statistics. To do so, you need to pass the option \ref enable-memory-stats "--enable-memory-stats" when running configure. It is then possible to call the function starpu_data_display_memory_stats() to display statistics about the current data handles registered within StarPU. Moreover, statistics will be displayed at the end of the execution on data handles which have not been cleared out. This can be disabled by setting the environment variable \ref STARPU_MEMORY_STATS to 0. For example, by adding a call to the function starpu_data_display_memory_stats() in the fblock example before unpartitioning the data, one will get something similar to: \verbatim $ STARPU_MEMORY_STATS=1 ./examples/filters/fblock ... #--------------------- Memory stats : #------- Data on Node #2 #----- Data : 0x5562074e8670 Size : 144 #-- Data access stats /!\ Work Underway Node #0 Direct access : 0 Loaded (Owner) : 0 Loaded (Shared) : 0 Invalidated (was Owner) : 1 Node #2 Direct access : 0 Loaded (Owner) : 1 Loaded (Shared) : 0 Invalidated (was Owner) : 0 #------- Data on Node #3 #----- Data : 0x5562074e9338 Size : 96 #-- Data access stats /!\ Work Underway Node #0 Direct access : 0 Loaded (Owner) : 0 Loaded (Shared) : 0 Invalidated (was Owner) : 1 Node #3 Direct access : 0 Loaded (Owner) : 1 Loaded (Shared) : 0 Invalidated (was Owner) : 0 #--------------------- ... \endverbatim \section DataStatistics Data Statistics Different data statistics can be displayed at the end of the execution of the application. To enable them, you need to define the environment variable \ref STARPU_ENABLE_STATS. When calling starpu_shutdown() various statistics will be displayed, execution, MSI cache statistics, allocation cache statistics, and data transfer statistics. The display can be disabled by setting the environment variable \ref STARPU_STATS to 0. \verbatim $ ./examples/cholesky/cholesky_tag Computation took (in ms) 518.16 Synthetic GFlops : 44.21 #--------------------- MSI cache stats : TOTAL MSI stats hit 1622 (66.23 %) miss 827 (33.77 %) ... \endverbatim \verbatim $ STARPU_STATS=0 ./examples/cholesky/cholesky_tag Computation took (in ms) 518.16 Synthetic GFlops : 44.21 \endverbatim // TODO: data transfer stats are similar to the ones displayed when // setting STARPU_BUS_STATS */