#include "gromacs/utility/fatalerror.h"
#include "gromacs/utility/gmxassert.h"
#include "gromacs/utility/stringutil.h"
+#include "gromacs/ewald/pme_coordinate_receiver_gpu.h"
#include "pme_gpu_internal.h"
#include "pme_gpu_settings.h"
void inline parallel_3dfft_execute_gpu_wrapper(gmx_pme_t* pme,
const int gridIndex,
enum gmx_fft_direction dir,
- gmx_wallcycle_t wcycle)
+ gmx_wallcycle* wcycle)
{
if (pme_gpu_settings(pme->gpu).performGPUFFT)
{
- wallcycle_start_nocount(wcycle, ewcLAUNCH_GPU);
- wallcycle_sub_start_nocount(wcycle, ewcsLAUNCH_GPU_PME);
+ wallcycle_start_nocount(wcycle, WallCycleCounter::LaunchGpu);
+ wallcycle_sub_start_nocount(wcycle, WallCycleSubCounter::LaunchGpuPme);
pme_gpu_3dfft(pme->gpu, dir, gridIndex);
- wallcycle_sub_stop(wcycle, ewcsLAUNCH_GPU_PME);
- wallcycle_stop(wcycle, ewcLAUNCH_GPU);
+ wallcycle_sub_stop(wcycle, WallCycleSubCounter::LaunchGpuPme);
+ wallcycle_stop(wcycle, WallCycleCounter::LaunchGpu);
}
else
{
- wallcycle_start(wcycle, ewcPME_FFT_MIXED_MODE);
+ wallcycle_start(wcycle, WallCycleCounter::PmeFftMixedMode);
#pragma omp parallel for num_threads(pme->nthread) schedule(static)
for (int thread = 0; thread < pme->nthread; thread++)
{
gmx_parallel_3dfft_execute(pme->pfft_setup[gridIndex], dir, thread, wcycle);
}
- wallcycle_stop(wcycle, ewcPME_FFT_MIXED_MODE);
+ wallcycle_stop(wcycle, WallCycleCounter::PmeFftMixedMode);
}
}
if (stepWork.haveDynamicBox || shouldUpdateBox) // || is to make the first computation always update
{
- wallcycle_start_nocount(wcycle, ewcLAUNCH_GPU);
- wallcycle_sub_start_nocount(wcycle, ewcsLAUNCH_GPU_PME);
+ wallcycle_start_nocount(wcycle, WallCycleCounter::LaunchGpu);
+ wallcycle_sub_start_nocount(wcycle, WallCycleSubCounter::LaunchGpuPme);
pme_gpu_update_input_box(pmeGpu, box);
- wallcycle_sub_stop(wcycle, ewcsLAUNCH_GPU_PME);
- wallcycle_stop(wcycle, ewcLAUNCH_GPU);
+ wallcycle_sub_stop(wcycle, WallCycleSubCounter::LaunchGpuPme);
+ wallcycle_stop(wcycle, WallCycleCounter::LaunchGpu);
if (!pme_gpu_settings(pmeGpu).performGPUSolve)
{
}
}
-void pme_gpu_launch_spread(gmx_pme_t* pme,
- GpuEventSynchronizer* xReadyOnDevice,
- gmx_wallcycle* wcycle,
- const real lambdaQ)
+void pme_gpu_launch_spread(gmx_pme_t* pme,
+ GpuEventSynchronizer* xReadyOnDevice,
+ gmx_wallcycle* wcycle,
+ const real lambdaQ,
+ const bool useGpuDirectComm,
+ gmx::PmeCoordinateReceiverGpu* pmeCoordinateReceiverGpu)
{
GMX_ASSERT(pme_gpu_active(pme), "This should be a GPU run of PME but it is not enabled.");
- GMX_ASSERT(!GMX_GPU_CUDA || xReadyOnDevice || !pme->bPPnode,
- "Need a valid xReadyOnDevice on PP+PME ranks with CUDA.");
+ GMX_ASSERT(xReadyOnDevice || !pme->bPPnode, "Need a valid xReadyOnDevice on PP+PME ranks.");
GMX_ASSERT(pme->doCoulomb, "Only Coulomb PME can be run on GPU.");
PmeGpu* pmeGpu = pme->gpu;
/* Spread the coefficients on a grid */
const bool computeSplines = true;
const bool spreadCharges = true;
- wallcycle_start_nocount(wcycle, ewcLAUNCH_GPU);
- wallcycle_sub_start_nocount(wcycle, ewcsLAUNCH_GPU_PME);
- pme_gpu_spread(pmeGpu, xReadyOnDevice, fftgrids, computeSplines, spreadCharges, lambdaQ);
- wallcycle_sub_stop(wcycle, ewcsLAUNCH_GPU_PME);
- wallcycle_stop(wcycle, ewcLAUNCH_GPU);
+ wallcycle_start_nocount(wcycle, WallCycleCounter::LaunchGpu);
+ wallcycle_sub_start_nocount(wcycle, WallCycleSubCounter::LaunchGpuPme);
+ pme_gpu_spread(
+ pmeGpu, xReadyOnDevice, fftgrids, computeSplines, spreadCharges, lambdaQ, useGpuDirectComm, pmeCoordinateReceiverGpu);
+ wallcycle_sub_stop(wcycle, WallCycleSubCounter::LaunchGpuPme);
+ wallcycle_stop(wcycle, WallCycleCounter::LaunchGpu);
}
void pme_gpu_launch_complex_transforms(gmx_pme_t* pme, gmx_wallcycle* wcycle, const gmx::StepWorkload& stepWork)
const bool computeEnergyAndVirial = stepWork.computeEnergy || stepWork.computeVirial;
if (!settings.performGPUFFT)
{
- wallcycle_start(wcycle, ewcWAIT_GPU_PME_SPREAD);
+ wallcycle_start(wcycle, WallCycleCounter::WaitGpuPmeSpread);
pme_gpu_sync_spread_grid(pme->gpu);
- wallcycle_stop(wcycle, ewcWAIT_GPU_PME_SPREAD);
+ wallcycle_stop(wcycle, WallCycleCounter::WaitGpuPmeSpread);
}
try
{
const auto gridOrdering =
settings.useDecomposition ? GridOrdering::YZX : GridOrdering::XYZ;
- wallcycle_start_nocount(wcycle, ewcLAUNCH_GPU);
- wallcycle_sub_start_nocount(wcycle, ewcsLAUNCH_GPU_PME);
+ wallcycle_start_nocount(wcycle, WallCycleCounter::LaunchGpu);
+ wallcycle_sub_start_nocount(wcycle, WallCycleSubCounter::LaunchGpuPme);
pme_gpu_solve(pmeGpu, gridIndex, cfftgrid, gridOrdering, computeEnergyAndVirial);
- wallcycle_sub_stop(wcycle, ewcsLAUNCH_GPU_PME);
- wallcycle_stop(wcycle, ewcLAUNCH_GPU);
+ wallcycle_sub_stop(wcycle, WallCycleSubCounter::LaunchGpuPme);
+ wallcycle_stop(wcycle, WallCycleCounter::LaunchGpu);
}
else
{
- wallcycle_start(wcycle, ewcPME_SOLVE_MIXED_MODE);
+ wallcycle_start(wcycle, WallCycleCounter::PmeSolveMixedMode);
#pragma omp parallel for num_threads(pme->nthread) schedule(static)
for (int thread = 0; thread < pme->nthread; thread++)
{
solve_pme_yzx(pme, cfftgrid, pme->boxVolume, computeEnergyAndVirial, pme->nthread, thread);
}
- wallcycle_stop(wcycle, ewcPME_SOLVE_MIXED_MODE);
+ wallcycle_stop(wcycle, WallCycleCounter::PmeSolveMixedMode);
}
parallel_3dfft_execute_gpu_wrapper(pme, gridIndex, GMX_FFT_COMPLEX_TO_REAL, wcycle);
return;
}
- wallcycle_start_nocount(wcycle, ewcLAUNCH_GPU);
- wallcycle_sub_start_nocount(wcycle, ewcsLAUNCH_GPU_PME);
+ wallcycle_start_nocount(wcycle, WallCycleCounter::LaunchGpu);
+ wallcycle_sub_start_nocount(wcycle, WallCycleSubCounter::LaunchGpuPme);
float** fftgrids = pme->fftgrid;
pme_gpu_gather(pme->gpu, fftgrids, lambdaQ);
- wallcycle_sub_stop(wcycle, ewcsLAUNCH_GPU_PME);
- wallcycle_stop(wcycle, ewcLAUNCH_GPU);
+ wallcycle_sub_stop(wcycle, WallCycleSubCounter::LaunchGpuPme);
+ wallcycle_stop(wcycle, WallCycleCounter::LaunchGpu);
}
//! Accumulate the \c forcesToAdd to \c f, using the available threads.
{
const int end = forceToAdd.size();
- int gmx_unused nt = gmx_omp_nthreads_get(emntPME);
+ int gmx_unused nt = gmx_omp_nthreads_get(ModuleMultiThread::Pme);
#pragma omp parallel for num_threads(nt) schedule(static)
for (int i = 0; i < end; i++)
{
gmx::ForceWithVirial* forceWithVirial,
gmx_enerdata_t* enerd)
{
- wallcycle_start(wcycle, ewcPME_GPU_F_REDUCTION);
+ wallcycle_start(wcycle, WallCycleCounter::PmeGpuFReduction);
GMX_ASSERT(forceWithVirial, "Invalid force pointer");
if (computeEnergyAndVirial)
{
sum_forces(forceWithVirial->force_, output.forces_);
}
- wallcycle_stop(wcycle, ewcPME_GPU_F_REDUCTION);
+ wallcycle_stop(wcycle, WallCycleCounter::PmeGpuFReduction);
}
bool pme_gpu_try_finish_task(gmx_pme_t* pme,
// TODO: implement c_streamQuerySupported with an additional GpuEventSynchronizer per stream (#2521)
if ((completionKind == GpuTaskCompletion::Check) && c_streamQuerySupported)
{
- wallcycle_start_nocount(wcycle, ewcWAIT_GPU_PME_GATHER);
+ wallcycle_start_nocount(wcycle, WallCycleCounter::WaitGpuPmeGather);
// Query the PME stream for completion of all tasks enqueued and
// if we're not done, stop the timer before early return.
const bool pmeGpuDone = pme_gpu_stream_query(pme->gpu);
- wallcycle_stop(wcycle, ewcWAIT_GPU_PME_GATHER);
+ wallcycle_stop(wcycle, WallCycleCounter::WaitGpuPmeGather);
if (!pmeGpuDone)
{
needToSynchronize = false;
}
- wallcycle_start(wcycle, ewcWAIT_GPU_PME_GATHER);
+ wallcycle_start(wcycle, WallCycleCounter::WaitGpuPmeGather);
// If the above check passed, then there is no need to make an
// explicit synchronization call.
if (needToSynchronize)
const bool computeEnergyAndVirial = stepWork.computeEnergy || stepWork.computeVirial;
PmeOutput output = pme_gpu_getOutput(
*pme, computeEnergyAndVirial, pme->gpu->common->ngrids > 1 ? lambdaQ : 1.0);
- wallcycle_stop(wcycle, ewcWAIT_GPU_PME_GATHER);
+ wallcycle_stop(wcycle, WallCycleCounter::WaitGpuPmeGather);
GMX_ASSERT(pme->gpu->settings.useGpuForceReduction == !output.haveForceOutput_,
"When forces are reduced on the CPU, there needs to be force output");
{
GMX_ASSERT(pme_gpu_active(pme), "This should be a GPU run of PME but it is not enabled.");
- wallcycle_start(wcycle, ewcWAIT_GPU_PME_GATHER);
+ wallcycle_start(wcycle, WallCycleCounter::WaitGpuPmeGather);
// Synchronize the whole PME stream at once, including D2H result transfers
// if there are outputs we need to wait for at this step; we still call getOutputs
PmeOutput output = pme_gpu_getOutput(
*pme, computeEnergyAndVirial, pme->gpu->common->ngrids > 1 ? lambdaQ : 1.0);
- wallcycle_stop(wcycle, ewcWAIT_GPU_PME_GATHER);
+ wallcycle_stop(wcycle, WallCycleCounter::WaitGpuPmeGather);
return output;
}
{
GMX_ASSERT(pme_gpu_active(pme), "This should be a GPU run of PME but it is not enabled.");
- wallcycle_start_nocount(wcycle, ewcLAUNCH_GPU);
- wallcycle_sub_start_nocount(wcycle, ewcsLAUNCH_GPU_PME);
+ wallcycle_start_nocount(wcycle, WallCycleCounter::LaunchGpu);
+ wallcycle_sub_start_nocount(wcycle, WallCycleSubCounter::LaunchGpuPme);
pme_gpu_update_timings(pme->gpu);
pme_gpu_clear_grids(pme->gpu);
pme_gpu_clear_energy_virial(pme->gpu);
- wallcycle_sub_stop(wcycle, ewcsLAUNCH_GPU_PME);
- wallcycle_stop(wcycle, ewcLAUNCH_GPU);
+ wallcycle_sub_stop(wcycle, WallCycleSubCounter::LaunchGpuPme);
+ wallcycle_stop(wcycle, WallCycleCounter::LaunchGpu);
}
DeviceBuffer<gmx::RVec> pme_gpu_get_device_f(const gmx_pme_t* pme)