/* * This file is part of the StarPU Handbook. * Copyright (C) 2009--2011 Universit@'e de Bordeaux 1 * Copyright (C) 2010, 2011, 2012, 2013 Centre National de la Recherche Scientifique * Copyright (C) 2011, 2012 Institut National de Recherche en Informatique et Automatique * See the file version.doxy for copying conditions. */ /*! \page HowToOptimizePerformanceWithStarPU How To Optimize Performance With StarPU TODO: improve! Simply encapsulating application kernels into tasks already permits to seamlessly support CPU and GPUs at the same time. To achieve good performance, a few additional changes are needed. \section DataManagement Data Management When the application allocates data, whenever possible it should use the function starpu_malloc(), which will ask CUDA or OpenCL to make the allocation itself and pin the corresponding allocated memory. This is needed to permit asynchronous data transfer, i.e. permit data transfer to overlap with computations. Otherwise, the trace will show that the DriverCopyAsync state takes a lot of time, this is because CUDA or OpenCL then reverts to synchronous transfers. By default, StarPU leaves replicates of data wherever they were used, in case they will be re-used by other tasks, thus saving the data transfer time. When some task modifies some data, all the other replicates are invalidated, and only the processing unit which ran that task will have a valid replicate of the data. If the application knows that this data will not be re-used by further tasks, it should advise StarPU to immediately replicate it to a desired list of memory nodes (given through a bitmask). This can be understood like the write-through mode of CPU caches. \code{.c} starpu_data_set_wt_mask(img_handle, 1<<0); \endcode will for instance request to always automatically transfer a replicate into the main memory (node 0), as bit 0 of the write-through bitmask is being set. \code{.c} starpu_data_set_wt_mask(img_handle, ~0U); \endcode will request to always automatically broadcast the updated data to all memory nodes. Setting the write-through mask to ~0U can also be useful to make sure all memory nodes always have a copy of the data, so that it is never evicted when memory gets scarse. Implicit data dependency computation can become expensive if a lot of tasks access the same piece of data. If no dependency is required on some piece of data (e.g. because it is only accessed in read-only mode, or because write accesses are actually commutative), use the function starpu_data_set_sequential_consistency_flag() to disable implicit dependencies on that data. In the same vein, accumulation of results in the same data can become a bottleneck. The use of the mode ::STARPU_REDUX permits to optimize such accumulation (see \ref DataReduction). To a lesser extent, the use of the flag ::STARPU_COMMUTE keeps the bottleneck, but at least permits the accumulation to happen in any order. Applications often need a data just for temporary results. In such a case, registration can be made without an initial value, for instance this produces a vector data: \code{.c} starpu_vector_data_register(&handle, -1, 0, n, sizeof(float)); \endcode StarPU will then allocate the actual buffer only when it is actually needed, e.g. directly on the GPU without allocating in main memory. In the same vein, once the temporary results are not useful any more, the data should be thrown away. If the handle is not to be reused, it can be unregistered: \code{.c} starpu_unregister_submit(handle); \endcode actual unregistration will be done after all tasks working on the handle terminate. If the handle is to be reused, instead of unregistering it, it can simply be invalidated: \code{.c} starpu_invalidate_submit(handle); \endcode the buffers containing the current value will then be freed, and reallocated only when another task writes some value to the handle. \section TaskGranularity Task Granularity Like any other runtime, StarPU has some overhead to manage tasks. Since it does smart scheduling and data management, that overhead is not always neglectable. The order of magnitude of the overhead is typically a couple of microseconds, which is actually quite smaller than the CUDA overhead itself. The amount of work that a task should do should thus be somewhat bigger, to make sure that the overhead becomes neglectible. The offline performance feedback can provide a measure of task length, which should thus be checked if bad performance are observed. To get a grasp at the scalability possibility according to task size, one can run tests/microbenchs/tasks_size_overhead.sh which draws curves of the speedup of independent tasks of very small sizes. The choice of scheduler also has impact over the overhead: for instance, the scheduler dmda takes time to make a decision, while eager does not. tasks_size_overhead.sh can again be used to get a grasp at how much impact that has on the target machine. \section TaskSubmission Task Submission To let StarPU make online optimizations, tasks should be submitted asynchronously as much as possible. Ideally, all the tasks should be submitted, and mere calls to starpu_task_wait_for_all() or starpu_data_unregister() be done to wait for termination. StarPU will then be able to rework the whole schedule, overlap computation with communication, manage accelerator local memory usage, etc. \section TaskPriorities Task Priorities By default, StarPU will consider the tasks in the order they are submitted by the application. If the application programmer knows that some tasks should be performed in priority (for instance because their output is needed by many other tasks and may thus be a bottleneck if not executed early enough), the field starpu_task::priority should be set to transmit the priority information to StarPU. \section TaskSchedulingPolicy Task Scheduling Policy By default, StarPU uses the simple greedy scheduler eager. This is because it provides correct load balance even if the application codelets do not have performance models. If your application codelets have performance models (\ref PerformanceModelExample), you should change the scheduler thanks to the environment variable \ref STARPU_SCHED. For instance export STARPU_SCHED=dmda . Use help to get the list of available schedulers. The eager scheduler uses a central task queue, from which workers draw tasks to work on. This however does not permit to prefetch data since the scheduling decision is taken late. If a task has a non-0 priority, it is put at the front of the queue. The prio scheduler also uses a central task queue, but sorts tasks by priority (between -5 and 5). The random scheduler distributes tasks randomly according to assumed worker overall performance. The ws (work stealing) scheduler schedules tasks on the local worker by default. When a worker becomes idle, it steals a task from the most loaded worker. The dm (deque model) scheduler uses task execution performance models into account to perform an HEFT-similar scheduling strategy: it schedules tasks where their termination time will be minimal. The dmda (deque model data aware) scheduler is similar to dm, it also takes into account data transfer time. The dmdar (deque model data aware ready) scheduler is similar to dmda, it also sorts tasks on per-worker queues by number of already-available data buffers. The dmdas (deque model data aware sorted) scheduler is similar to dmda, it also supports arbitrary priority values. The heft (heterogeneous earliest finish time) scheduler is deprecated. It is now just an alias for dmda. The pheft (parallel HEFT) scheduler is similar to heft, it also supports parallel tasks (still experimental). Should not be used when several contexts using it are being executed simultaneously. The peager (parallel eager) scheduler is similar to eager, it also supports parallel tasks (still experimental). Should not be used when several contexts using it are being executed simultaneously. \section PerformanceModelCalibration Performance Model Calibration Most schedulers are based on an estimation of codelet duration on each kind of processing unit. For this to be possible, the application programmer needs to configure a performance model for the codelets of the application (see \ref PerformanceModelExample for instance). History-based performance models use on-line calibration. StarPU will automatically calibrate codelets which have never been calibrated yet, and save the result in $STARPU_HOME/.starpu/sampling/codelets. The models are indexed by machine name. To share the models between machines (e.g. for a homogeneous cluster), use export STARPU_HOSTNAME=some_global_name. To force continuing calibration, use export STARPU_CALIBRATE=1 . This may be necessary if your application has not-so-stable performance. StarPU will force calibration (and thus ignore the current result) until 10 (_STARPU_CALIBRATION_MINIMUM) measurements have been made on each architecture, to avoid badly scheduling tasks just because the first measurements were not so good. Details on the current performance model status can be obtained from the command starpu_perfmodel_display: the -l option lists the available performance models, and the -s option permits to choose the performance model to be displayed. The result looks like: \verbatim $ starpu_perfmodel_display -s starpu_slu_lu_model_11 performance model for cpu_impl_0 # hash size flops mean dev n 914f3bef 1048576 0.000000e+00 2.503577e+04 1.982465e+02 8 3e921964 65536 0.000000e+00 5.527003e+02 1.848114e+01 7 e5a07e31 4096 0.000000e+00 1.717457e+01 5.190038e+00 14 ... \endverbatim Which shows that for the LU 11 kernel with a 1MiB matrix, the average execution time on CPUs was about 25ms, with a 0.2ms standard deviation, over 8 samples. It is a good idea to check this before doing actual performance measurements. A graph can be drawn by using the tool starpu_perfmodel_plot: \verbatim $ starpu_perfmodel_plot -s starpu_slu_lu_model_11 4096 16384 65536 262144 1048576 4194304 $ gnuplot starpu_starpu_slu_lu_model_11.gp $ gv starpu_starpu_slu_lu_model_11.eps \endverbatim \image html starpu_starpu_slu_lu_model_11.png \image latex starpu_starpu_slu_lu_model_11.eps "" width=\textwidth If a kernel source code was modified (e.g. performance improvement), the calibration information is stale and should be dropped, to re-calibrate from start. This can be done by using export STARPU_CALIBRATE=2. Note: due to CUDA limitations, to be able to measure kernel duration, calibration mode needs to disable asynchronous data transfers. Calibration thus disables data transfer / computation overlapping, and should thus not be used for eventual benchmarks. Note 2: history-based performance models get calibrated only if a performance-model-based scheduler is chosen. The history-based performance models can also be explicitly filled by the application without execution, if e.g. the application already has a series of measurements. This can be done by using starpu_perfmodel_update_history(), for instance: \code{.c} static struct starpu_perfmodel perf_model = { .type = STARPU_HISTORY_BASED, .symbol = "my_perfmodel", }; struct starpu_codelet cl = { .where = STARPU_CUDA, .cuda_funcs = { cuda_func1, cuda_func2, NULL }, .nbuffers = 1, .modes = {STARPU_W}, .model = &perf_model }; void feed(void) { struct my_measure *measure; struct starpu_task task; starpu_task_init(&task); task.cl = &cl; for (measure = &measures[0]; measure < measures[last]; measure++) { starpu_data_handle_t handle; starpu_vector_data_register(&handle, -1, 0, measure->size, sizeof(float)); task.handles[0] = handle; starpu_perfmodel_update_history(&perf_model, &task, STARPU_CUDA_DEFAULT + measure->cudadev, 0, measure->implementation, measure->time); starpu_task_clean(&task); starpu_data_unregister(handle); } } \endcode Measurement has to be provided in milliseconds for the completion time models, and in Joules for the energy consumption models. \section TaskDistributionVsDataTransfer Task Distribution Vs Data Transfer Distributing tasks to balance the load induces data transfer penalty. StarPU thus needs to find a balance between both. The target function that the scheduler dmda of StarPU tries to minimize is alpha * T_execution + beta * T_data_transfer, where T_execution is the estimated execution time of the codelet (usually accurate), and T_data_transfer is the estimated data transfer time. The latter is estimated based on bus calibration before execution start, i.e. with an idle machine, thus without contention. You can force bus re-calibration by running the tool starpu_calibrate_bus. The beta parameter defaults to 1, but it can be worth trying to tweak it by using export STARPU_SCHED_BETA=2 for instance, since during real application execution, contention makes transfer times bigger. This is of course imprecise, but in practice, a rough estimation already gives the good results that a precise estimation would give. \section DataPrefetch Data Prefetch The scheduling policies heft, dmda and pheft perform data prefetch (see \ref STARPU_PREFETCH): as soon as a scheduling decision is taken for a task, requests are issued to transfer its required data to the target processing unit, if needed, so that when the processing unit actually starts the task, its data will hopefully be already available and it will not have to wait for the transfer to finish. The application may want to perform some manual prefetching, for several reasons such as excluding initial data transfers from performance measurements, or setting up an initial statically-computed data distribution on the machine before submitting tasks, which will thus guide StarPU toward an initial task distribution (since StarPU will try to avoid further transfers). This can be achieved by giving the function starpu_data_prefetch_on_node() the handle and the desired target memory node. \section Power-basedScheduling Power-based Scheduling If the application can provide some power performance model (through the field starpu_codelet::power_model), StarPU will take it into account when distributing tasks. The target function that the scheduler dmda minimizes becomes alpha * T_execution + beta * T_data_transfer + gamma * Consumption , where Consumption is the estimated task consumption in Joules. To tune this parameter, use export STARPU_SCHED_GAMMA=3000 for instance, to express that each Joule (i.e kW during 1000us) is worth 3000us execution time penalty. Setting alpha and beta to zero permits to only take into account power consumption. This is however not sufficient to correctly optimize power: the scheduler would simply tend to run all computations on the most energy-conservative processing unit. To account for the consumption of the whole machine (including idle processing units), the idle power of the machine should be given by setting export STARPU_IDLE_POWER=200 for 200W, for instance. This value can often be obtained from the machine power supplier. The power actually consumed by the total execution can be displayed by setting export STARPU_PROFILING=1 STARPU_WORKER_STATS=1 . On-line task consumption measurement is currently only supported through the CL_PROFILING_POWER_CONSUMED OpenCL extension, implemented in the MoviSim simulator. Applications can however provide explicit measurements by using the function starpu_perfmodel_update_history() (examplified in \ref PerformanceModelExample with the power_model performance model). Fine-grain measurement is often not feasible with the feedback provided by the hardware, so the user can for instance run a given task a thousand times, measure the global consumption for that series of tasks, divide it by a thousand, repeat for varying kinds of tasks and task sizes, and eventually feed StarPU with these manual measurements through starpu_perfmodel_update_history(). \section StaticScheduling Static Scheduling In some cases, one may want to force some scheduling, for instance force a given set of tasks to GPU0, another set to GPU1, etc. while letting some other tasks be scheduled on any other device. This can indeed be useful to guide StarPU into some work distribution, while still letting some degree of dynamism. For instance, to force execution of a task on CUDA0: \code{.c} task->execute_on_a_specific_worker = 1; task->worker = starpu_worker_get_by_type(STARPU_CUDA_WORKER, 0); \endcode Note however that using scheduling contexts while statically scheduling tasks on workers could be tricky. Be careful to schedule the tasks exactly on the workers of the corresponding contexts, otherwise the workers' corresponding scheduling structures may not be allocated or the execution of the application may deadlock. Moreover, the hypervisor should not be used when statically scheduling tasks. \section Profiling Profiling A quick view of how many tasks each worker has executed can be obtained by setting export STARPU_WORKER_STATS=1 This is a convenient way to check that execution did happen on accelerators without penalizing performance with the profiling overhead. A quick view of how much data transfers have been issued can be obtained by setting export STARPU_BUS_STATS=1 . More detailed profiling information can be enabled by using export STARPU_PROFILING=1 or by calling starpu_profiling_status_set() from the source code. Statistics on the execution can then be obtained by using export STARPU_BUS_STATS=1 and export STARPU_WORKER_STATS=1 . More details on performance feedback are provided by the next chapter. \section DetectionStuckConditions Detection Stuck Conditions It may happen that for some reason, StarPU does not make progress for a long period of time. Reason are sometimes due to contention inside StarPU, but sometimes this is due to external reasons, such as stuck MPI driver, or CUDA driver, etc. export STARPU_WATCHDOG_TIMEOUT=10000 allows to make StarPU print an error message whenever StarPU does not terminate any task for 10ms. In addition to that, export STARPU_WATCHDOG_CRASH=1 triggers a crash in that condition, thus allowing to catch the situation in gdb etc. \section CUDA-specificOptimizations CUDA-specific Optimizations Due to CUDA limitations, StarPU will have a hard time overlapping its own communications and the codelet computations if the application does not use a dedicated CUDA stream for its computations instead of the default stream, which synchronizes all operations of the GPU. StarPU provides one by the use of starpu_cuda_get_local_stream() which can be used by all CUDA codelet operations to avoid this issue. For instance: \code{.c} func <<>> (foo, bar); cudaStreamSynchronize(starpu_cuda_get_local_stream()); \endcode StarPU already does appropriate calls for the CUBLAS library. Unfortunately, some CUDA libraries do not have stream variants of kernels. That will lower the potential for overlapping. \section PerformanceDebugging Performance Debugging To get an idea of what is happening, a lot of performance feedback is available, detailed in the next 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 SimulatedPerformance Simulated Performance StarPU can use Simgrid in order to simulate execution on an arbitrary platform. \subsection Calibration Calibration The idea is to first compile StarPU normally, and run the application, so as to automatically benchmark the bus and the codelets. \verbatim $ ./configure && make $ STARPU_SCHED=dmda ./examples/matvecmult/matvecmult [starpu][_starpu_load_history_based_model] Warning: model matvecmult is not calibrated, forcing calibration for this run. Use the STARPU_CALIBRATE environment variable to control this. $ ... $ STARPU_SCHED=dmda ./examples/matvecmult/matvecmult TEST PASSED \endverbatim Note that we force to use the scheduler dmda to generate performance models for the application. The application may need to be run several times before the model is calibrated. \subsection Simulation Simulation Then, recompile StarPU, passing \ref enable-simgrid "--enable-simgrid" to ./configure, and re-run the application: \verbatim $ ./configure --enable-simgrid && make $ STARPU_SCHED=dmda ./examples/matvecmult/matvecmult TEST FAILED !!! \endverbatim It is normal that the test fails: since the computation are not actually done (that is the whole point of simgrid), the result is wrong, of course. If the performance model is not calibrated enough, the following error message will be displayed \verbatim $ STARPU_SCHED=dmda ./examples/matvecmult/matvecmult [starpu][_starpu_load_history_based_model] Warning: model matvecmult is not calibrated, forcing calibration for this run. Use the STARPU_CALIBRATE environment variable to control this. [starpu][_starpu_simgrid_execute_job][assert failure] Codelet matvecmult does not have a perfmodel, or is not calibrated enough \endverbatim The number of devices can be chosen as usual with \ref STARPU_NCPU, \ref STARPU_NCUDA, and \ref STARPU_NOPENCL. For now, only the number of cpus can be arbitrarily chosen. The number of CUDA and OpenCL devices have to be lower than the real number on the current machine. The amount of simulated GPU memory is for now unbound by default, but it can be chosen by hand through the \ref STARPU_LIMIT_CUDA_MEM, \ref STARPU_LIMIT_CUDA_devid_MEM, \ref STARPU_LIMIT_OPENCL_MEM, and \ref STARPU_LIMIT_OPENCL_devid_MEM environment variables. The Simgrid default stack size is small; to increase it use the parameter --cfg=contexts/stack_size, for example: \verbatim $ ./example --cfg=contexts/stack_size:8192 TEST FAILED !!! \endverbatim Note: of course, if the application uses gettimeofday to make its performance measurements, the real time will be used, which will be bogus. To get the simulated time, it has to use starpu_timing_now() which returns the virtual timestamp in ms. \subsection SimulationOnAnotherMachine Simulation On Another Machine The simgrid support even permits to perform simulations on another machine, your desktop, typically. To achieve this, one still needs to perform the Calibration step on the actual machine to be simulated, then copy them to your desktop machine (the $STARPU_HOME/.starpu directory). One can then perform the Simulation step on the desktop machine, by setting the environment variable \ref STARPU_HOSTNAME to the name of the actual machine, to make StarPU use the performance models of the simulated machine even on the desktop machine. If the desktop machine does not have CUDA or OpenCL, StarPU is still able to use simgrid to simulate execution with CUDA/OpenCL devices, but the application source code will probably disable the CUDA and OpenCL codelets in thatcd sc case. Since during simgrid execution, the functions of the codelet are actually not called, one can use dummy functions such as the following to still permit CUDA or OpenCL execution: \snippet simgrid.c To be included */