gallo/atrip
1
0
Fork 0
Code Issues Pull Requests Projects Releases Wiki Activity

Update main Atrip.cxx using several gpus

Browse Source
This commit is contained in:
Gallo Alejandro 2022-08-12 18:30:55 +02:00
parent b4aef4db9e
commit c2e9e930ba
3 changed files with 104 additions and 56 deletions
Show Stats Download Patch File Download Diff File Expand all files Collapse all files

158
src/atrip/Atrip.cxx
View File

@ -24,13 +24,7 @@
using namespace atrip; using namespace atrip;
#if defined(HAVE_CUDA) #if defined(HAVE_CUDA)
#include <cuda.h>
namespace atrip {
namespace cuda {
};
};
#endif #endif
template <typename F> bool RankMap<F>::RANK_ROUND_ROBIN; template <typename F> bool RankMap<F>::RANK_ROUND_ROBIN;
@ -40,6 +34,7 @@ size_t Atrip::rank;
size_t Atrip::np; size_t Atrip::np;
#if defined(HAVE_CUDA) #if defined(HAVE_CUDA)
typename Atrip::CudaContext Atrip::cuda; typename Atrip::CudaContext Atrip::cuda;
typename Atrip::KernelDimensions Atrip::kernelDimensions;
#endif #endif
MPI_Comm Atrip::communicator; MPI_Comm Atrip::communicator;
Timings Atrip::chrono; Timings Atrip::chrono;
@ -74,20 +69,99 @@ Atrip::Output Atrip::run(Atrip::Input<F> const& in) {
LOG(0,"Atrip") << "Nv: " << Nv << "\n"; LOG(0,"Atrip") << "Nv: " << Nv << "\n";
LOG(0,"Atrip") << "np: " << np << "\n"; LOG(0,"Atrip") << "np: " << np << "\n";
#if defined(HAVE_CUDA)
int ngcards;
cuDeviceGetCount(&ngcards);
LOG(0,"Atrip") << "ngcards: " << ngcards << "\n";
if (np > ngcards) {
std::cerr << "ATRIP: You are running on more ranks than the number of graphic cards\n"
<< "You have " << ngcards << " cards at your disposal\n";
throw "";
}
if (np < ngcards) {
std::cerr << "You have " << ngcards << " cards at your disposal\n"
<< "You will be only using " << np << ", i.e., the nubmer of ranks.\n";
}
for (size_t _rank = 0; _rank < np; _rank++) {
if (rank == _rank) {
CUcontext ctx;
CUdevice dev;
CUdevprop prop;
struct { struct { size_t free, total; } avail; size_t total; } memory;
char *name = (char*)malloc(256);
// set current device
cuDeviceGet(&dev, rank);
cuCtxCreate(&ctx, 0, dev);
cuCtxSetCurrent(ctx);
// get information of the device
cuDeviceGetProperties(&prop, dev);
cuMemGetInfo(&memory.avail.free, &memory.avail.total);
cuDeviceGetName(name, 256, dev);
cuDeviceTotalMem(&memory.total, dev);
printf("\n"
"CUDA CARD RANK %d\n"
"=================\n"
"\tnumber: %1$d\n"
"\tname: %s\n"
"\tMem. clock rate (KHz): %d\n"
"\tShared Mem Per Block (KB): %f\n"
"\tAvail. Free/Total mem (GB): %f/%f\n"
"\tFree memory (GB): %f\n"
"\n",
Atrip::rank,
name,
prop.clockRate,
prop.sharedMemPerBlock / 1024.0,
memory.avail.free / 1024.0 / 1024.0 / 1024.0 ,
memory.avail.total / 1024.0 / 1024.0 / 1024.0,
memory.total / 1024.0 / 1024.0 / 1024.0
);
std::free((void*)name);
}
MPI_Barrier(universe);
}
if (in.oooThreads > 0) {
Atrip::kernelDimensions.ooo.threads = in.oooThreads;
}
if (in.oooBlocks > 0) {
Atrip::kernelDimensions.ooo.blocks = in.oooBlocks;
}
if (Atrip::kernelDimensions.ooo.threads <= 0 ||
Atrip::kernelDimensions.ooo.blocks <= 0) {
Atrip::kernelDimensions.ooo.blocks = No / 32 + No % 32;
Atrip::kernelDimensions.ooo.threads = 32;
}
LOG(0,"Atrip") << "ooo blocks: "
<< Atrip::kernelDimensions.ooo.blocks << "\n";
LOG(0,"Atrip") << "ooo threads per block: "
<< Atrip::kernelDimensions.ooo.threads << "\n";
#endif
// allocate the three scratches, see piecuch // allocate the three scratches, see piecuch
// we need local copies of the following tensors on every // we need local copies of the following tensors on every
// rank // rank
std::vector<F> _epsi(No) std::vector<F> _epsi(No), _epsa(Nv), _Tai(No * Nv);
, _epsa(Nv)
, _Tai(No * Nv)
;
// copy the data from the tensors into the vectors
in.ei->read_all(_epsi.data()); in.ei->read_all(_epsi.data());
in.ea->read_all(_epsa.data()); in.ea->read_all(_epsa.data());
in.Tph->read_all(_Tai.data()); in.Tph->read_all(_Tai.data());
//TODO: free memory pointers in the end of the algorithm
DataPtr<F> Tijk, Zijk;
#if defined(HAVE_CUDA) #if defined(HAVE_CUDA)
DataPtr<F> Tai, epsi, epsa; DataPtr<F> Tai, epsi, epsa;
//TODO: free memory pointers in the end of the algorithm
cuMemAlloc(&Tai, sizeof(F) * _Tai.size()); cuMemAlloc(&Tai, sizeof(F) * _Tai.size());
cuMemAlloc(&epsi, sizeof(F) * _epsi.size()); cuMemAlloc(&epsi, sizeof(F) * _epsi.size());
cuMemAlloc(&epsa, sizeof(F) * _epsa.size()); cuMemAlloc(&epsa, sizeof(F) * _epsa.size());
@ -96,13 +170,12 @@ Atrip::Output Atrip::run(Atrip::Input<F> const& in) {
cuMemcpyHtoD(epsi,(void*)_epsi.data(), sizeof(F) * _epsi.size()); cuMemcpyHtoD(epsi,(void*)_epsi.data(), sizeof(F) * _epsi.size());
cuMemcpyHtoD(epsa, (void*)_epsa.data(), sizeof(F) * _epsa.size()); cuMemcpyHtoD(epsa, (void*)_epsa.data(), sizeof(F) * _epsa.size());
DataPtr<F> Tijk, Zijk;
//TODO: free memory
cuMemAlloc(&Tijk, sizeof(F) * No * No * No); cuMemAlloc(&Tijk, sizeof(F) * No * No * No);
cuMemAlloc(&Zijk, sizeof(F) * No * No * No); cuMemAlloc(&Zijk, sizeof(F) * No * No * No);
#else #else
std::vector<F> &Tai = _Tai, &epsi = _epsi, &epsa = _epsa; std::vector<F> &Tai = _Tai, &epsi = _epsi, &epsa = _epsa;
std::vector<F> Tijk(No*No*No), Zijk(No*No*No); Zijk = (DataFieldType<F>*)malloc(No*No*No * sizeof(DataFieldType<F>));
Tijk = (DataFieldType<F>*)malloc(No*No*No * sizeof(DataFieldType<F>));
#endif #endif
RankMap<F>::RANK_ROUND_ROBIN = in.rankRoundRobin; RankMap<F>::RANK_ROUND_ROBIN = in.rankRoundRobin;
@ -135,7 +208,7 @@ Atrip::Output Atrip::run(Atrip::Input<F> const& in) {
// BUILD SLICES PARAMETRIZED BY NV x NV =============================={{{1 // BUILD SLICES PARAMETRIZED BY NV x NV =============================={{{1
WITH_CHRONO("nv-nv-slices", WITH_CHRONO("nv-nv-slices",
LOG(0,"Atrip") << "BUILD NV x NV-SLICES\n"; LOG(0,"Atrip") << "building NV x NV slices\n";
ABPH<F> abph(*in.Vppph, (size_t)No, (size_t)Nv, (size_t)np, child_comm, universe); ABPH<F> abph(*in.Vppph, (size_t)No, (size_t)Nv, (size_t)np, child_comm, universe);
ABHH<F> abhh(*in.Vpphh, (size_t)No, (size_t)Nv, (size_t)np, child_comm, universe); ABHH<F> abhh(*in.Vpphh, (size_t)No, (size_t)Nv, (size_t)np, child_comm, universe);
TABHH<F> tabhh(*in.Tpphh, (size_t)No, (size_t)Nv, (size_t)np, child_comm, universe); TABHH<F> tabhh(*in.Tpphh, (size_t)No, (size_t)Nv, (size_t)np, child_comm, universe);
@ -148,7 +221,7 @@ Atrip::Output Atrip::run(Atrip::Input<F> const& in) {
// BUILD SLICES PARAMETRIZED BY NV ==================================={{{1 // BUILD SLICES PARAMETRIZED BY NV ==================================={{{1
WITH_CHRONO("nv-slices", WITH_CHRONO("nv-slices",
LOG(0,"Atrip") << "BUILD NV-SLICES\n"; LOG(0,"Atrip") << "building NV slices\n";
TAPHH<F> taphh(*in.Tpphh, (size_t)No, (size_t)Nv, (size_t)np, child_comm, universe); TAPHH<F> taphh(*in.Tpphh, (size_t)No, (size_t)Nv, (size_t)np, child_comm, universe);
HHHA<F> hhha(*in.Vhhhp, (size_t)No, (size_t)Nv, (size_t)np, child_comm, universe); HHHA<F> hhha(*in.Vhhhp, (size_t)No, (size_t)Nv, (size_t)np, child_comm, universe);
) )
@ -373,9 +446,6 @@ Atrip::Output Atrip::run(Atrip::Input<F> const& in) {
} }
} }
LOG(0, "AtripCUDA") << "Starting iterations\n";
for ( size_t for ( size_t
i = first_iteration, i = first_iteration,
iteration = first_iteration + 1 iteration = first_iteration + 1
@ -384,8 +454,6 @@ Atrip::Output Atrip::run(Atrip::Input<F> const& in) {
) { ) {
Atrip::chrono["iterations"].start(); Atrip::chrono["iterations"].start();
LOG(0, "AtripCUDA") << "iteration " << i << "\n";
// check overhead from chrono over all iterations // check overhead from chrono over all iterations
WITH_CHRONO("start:stop", {}) WITH_CHRONO("start:stop", {})
@ -397,8 +465,8 @@ Atrip::Output Atrip::run(Atrip::Input<F> const& in) {
// write checkpoints // write checkpoints
// TODO: ENABLE THIS
if (iteration % checkpoint_mod == 0 && false) { if (iteration % checkpoint_mod == 0 && false) {
LOG(0, "AtripCUDA") << "checkpoints \n";
double globalEnergy = 0; double globalEnergy = 0;
MPI_Reduce(&energy, &globalEnergy, 1, MPI_DOUBLE, MPI_SUM, 0, universe); MPI_Reduce(&energy, &globalEnergy, 1, MPI_DOUBLE, MPI_SUM, 0, universe);
Checkpoint out Checkpoint out
@ -410,10 +478,9 @@ Atrip::Output Atrip::run(Atrip::Input<F> const& in) {
iteration - 1, iteration - 1,
in.rankRoundRobin}; in.rankRoundRobin};
LOG(0, "Atrip") << "Writing checkpoint\n"; LOG(0, "Atrip") << "Writing checkpoint\n";
//if (Atrip::rank == 0) write_checkpoint(out, in.checkpointPath); if (Atrip::rank == 0) write_checkpoint(out, in.checkpointPath);
} }
LOG(0, "AtripCUDA") << "reporting \n";
// write reporting // write reporting
if (iteration % iterationMod == 0 || iteration == iteration1Percent) { if (iteration % iterationMod == 0 || iteration == iteration1Percent) {
@ -467,32 +534,20 @@ Atrip::Output Atrip::run(Atrip::Input<F> const& in) {
<< "\n"; << "\n";
) )
LOG(0, "AtripCUDA") << "first database " << i << "\n";
// COMM FIRST DATABASE ================================================{{{1 // COMM FIRST DATABASE ================================================{{{1
if (i == first_iteration) { if (i == first_iteration) {
LOG(0, "AtripCUDA") << "first database " << i << "\n";
WITH_RANK << "__first__:first database ............ \n"; WITH_RANK << "__first__:first database ............ \n";
const auto db = communicateDatabase(abc, universe); const auto db = communicateDatabase(abc, universe);
LOG(0, "AtripCUDA") << "first database communicated" << i << "\n";
WITH_RANK << "__first__:first database communicated \n"; WITH_RANK << "__first__:first database communicated \n";
WITH_RANK << "__first__:first database io phase \n"; WITH_RANK << "__first__:first database io phase \n";
LOG(0, "AtripCUDA") << "doing io " << i << "\n";
doIOPhase(db); doIOPhase(db);
LOG(0, "AtripCUDA") << "io done " << i << "\n";
WITH_RANK << "__first__:first database io phase DONE\n"; WITH_RANK << "__first__:first database io phase DONE\n";
WITH_RANK << "__first__::::Unwrapping all slices for first database\n"; WITH_RANK << "__first__::::Unwrapping all slices for first database\n";
LOG(0, "AtripCUDA") << "unrwapping " << i << "\n";
for (auto& u: unions) u->unwrapAll(abc); for (auto& u: unions) u->unwrapAll(abc);
LOG(0, "AtripCUDA") << "unwrapped " << i << "\n";
WITH_RANK << "__first__::::Unwrapping slices for first database DONE\n"; WITH_RANK << "__first__::::Unwrapping slices for first database DONE\n";
LOG(0, "AtripCUDA") << "barrier " << i << "\n";
MPI_Barrier(universe); MPI_Barrier(universe);
LOG(0, "AtripCUDA") << "barriered " << i << "\n";
} }
LOG(0, "AtripCUDA") << "next database" << i << "\n";
// COMM NEXT DATABASE ================================================={{{1 // COMM NEXT DATABASE ================================================={{{1
if (abcNext) { if (abcNext) {
WITH_RANK << "__comm__:" << iteration << "th communicating database\n"; WITH_RANK << "__comm__:" << iteration << "th communicating database\n";
@ -508,9 +563,6 @@ Atrip::Output Atrip::run(Atrip::Input<F> const& in) {
// COMPUTE DOUBLES ===================================================={{{1 // COMPUTE DOUBLES ===================================================={{{1
OCD_Barrier(universe); OCD_Barrier(universe);
if (!isFakeTuple(i)) { if (!isFakeTuple(i)) {
LOG(0, "AtripCUDA") << "computing doubles " << i << "\n";
WITH_RANK << iteration << "-th doubles\n"; WITH_RANK << iteration << "-th doubles\n";
WITH_CHRONO("oneshot-unwrap", WITH_CHRONO("oneshot-unwrap",
WITH_CHRONO("unwrap", WITH_CHRONO("unwrap",
@ -542,11 +594,7 @@ Atrip::Output Atrip::run(Atrip::Input<F> const& in) {
, tabhh.unwrapSlice(Slice<F>::AC, abc) , tabhh.unwrapSlice(Slice<F>::AC, abc)
, tabhh.unwrapSlice(Slice<F>::BC, abc) , tabhh.unwrapSlice(Slice<F>::BC, abc)
// -- TIJK // -- TIJK
#if defined(HAVE_CUDA)
, (DataFieldType<F>*)Tijk , (DataFieldType<F>*)Tijk
#else
, Tijk.data()
#endif
); );
WITH_RANK << iteration << "-th doubles done\n"; WITH_RANK << iteration << "-th doubles done\n";
)) ))
@ -563,16 +611,10 @@ Atrip::Output Atrip::run(Atrip::Input<F> const& in) {
WITH_CHRONO("reorder", WITH_CHRONO("reorder",
int ooo = No*No*No, stride = 1; int ooo = No*No*No, stride = 1;
atrip::xcopy<F>(&ooo, atrip::xcopy<F>(&ooo,
#if defined(HAVE_CUDA)
(DataFieldType<F>*)Tijk, &stride, (DataFieldType<F>*)Tijk, &stride,
(DataFieldType<F>*)Zijk, &stride); (DataFieldType<F>*)Zijk, &stride);
#else
(DataFieldType<F>*)Tijk.data(), &stride,
(DataFieldType<F>*)Zijk.data(), &stride);
#endif
) )
WITH_CHRONO("singles", WITH_CHRONO("singles",
LOG(0, "AtripCUDA") << "doing singles" << i << "\n";
#if defined(HAVE_CUDA) #if defined(HAVE_CUDA)
singlesContribution<F><<<1,1>>>( No, Nv, abc[0], abc[1], abc[2] singlesContribution<F><<<1,1>>>( No, Nv, abc[0], abc[1], abc[2]
, (DataFieldType<F>*)Tai , (DataFieldType<F>*)Tai
@ -583,13 +625,8 @@ Atrip::Output Atrip::run(Atrip::Input<F> const& in) {
, (DataFieldType<F>*)abhh.unwrapSlice(Slice<F>::AB, abc) , (DataFieldType<F>*)abhh.unwrapSlice(Slice<F>::AB, abc)
, (DataFieldType<F>*)abhh.unwrapSlice(Slice<F>::AC, abc) , (DataFieldType<F>*)abhh.unwrapSlice(Slice<F>::AC, abc)
, (DataFieldType<F>*)abhh.unwrapSlice(Slice<F>::BC, abc) , (DataFieldType<F>*)abhh.unwrapSlice(Slice<F>::BC, abc)
#if defined(HAVE_CUDA)
, (DataFieldType<F>*)Zijk); , (DataFieldType<F>*)Zijk);
#else
, Zijk.data());
#endif
) )
LOG(0, "AtripCUDA") << "singles done" << i << "\n";
} }
@ -602,7 +639,7 @@ Atrip::Output Atrip::run(Atrip::Input<F> const& in) {
if (abc[1] == abc[2]) distinct--; if (abc[1] == abc[2]) distinct--;
const F epsabc(_epsa[abc[0]] + _epsa[abc[1]] + _epsa[abc[2]]); const F epsabc(_epsa[abc[0]] + _epsa[abc[1]] + _epsa[abc[2]]);
LOG(0, "AtripCUDA") << "doing energy " << i << "distinct " << distinct << "\n"; // LOG(0, "AtripCUDA") << "doing energy " << i << "distinct " << distinct << "\n";
WITH_CHRONO("energy", WITH_CHRONO("energy",
/* /*
TODO: think about how to do this on the GPU in the best way possible TODO: think about how to do this on the GPU in the best way possible
@ -686,6 +723,17 @@ Atrip::Output Atrip::run(Atrip::Input<F> const& in) {
} }
// END OF MAIN LOOP // END OF MAIN LOOP
#if defined(HAVE_CUDA)
cuMemFree(Tai);
cuMemFree(epsi);
cuMemFree(epsa);
cuMemFree(Tijk);
cuMemFree(Zijk);
#else
std::free(Zijk);
std::free(Tijk);
#endif
MPI_Barrier(universe); MPI_Barrier(universe);
// PRINT TUPLES %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%{{{1 // PRINT TUPLES %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%{{{1

1
src/atrip/Blas.cxx
View File

@ -80,7 +80,6 @@ namespace atrip {
typename DataField<Complex>::type *C, typename DataField<Complex>::type *C,
const int *ldc) { const int *ldc) {
#if defined(HAVE_CUDA) #if defined(HAVE_CUDA)
#pragma warning HAVE_CUDA
cuDoubleComplex cuDoubleComplex
cu_alpha = {std::real(*alpha), std::imag(*alpha)}, cu_alpha = {std::real(*alpha), std::imag(*alpha)},
cu_beta = {std::real(*beta), std::imag(*beta)}; cu_beta = {std::real(*beta), std::imag(*beta)};

1
src/atrip/Equations.cxx
View File

@ -14,6 +14,7 @@
// [[file:~/cuda/atrip/atrip.org::*Prolog][Prolog:2]] // [[file:~/cuda/atrip/atrip.org::*Prolog][Prolog:2]]
#include<atrip/Equations.hpp> #include<atrip/Equations.hpp>
#include<atrip/CUDA.hpp>
#if defined(HAVE_CUDA) #if defined(HAVE_CUDA)
#include <cuda.h> #include <cuda.h>