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sparse_mp3.cxx
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sparse_mp3.cxx
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/** \addtogroup examples
* @{
* \defgroup sparse_mp3 sparse_mp3
* @{
* \brief Third-order Moller-Plesset perturbation theory (MP3) with sparse integrals. Equations adapted from those in Aquarius (credit to Devin Matthews)
*/
#include <ctf.hpp>
#include <float.h>
using namespace CTF;
struct dpair {
double a, b;
dpair(){ a=0.0; b=0.0; }
dpair(double a_, double b_){ a=a_, b=b_;}
dpair operator+(dpair const & p) const { return dpair(a+p.a, b+p.b); }
};
namespace CTF {
template <>
inline void Set<dpair>::print(char const * p, FILE * fp) const {
fprintf(fp,"(a=%lf b=%lf)",((dpair*)p)->a, ((dpair*)p)->b);
}
}
void divide_EaEi(Tensor<> & Ea,
Tensor<> & Ei,
Tensor<> & T,
bool sparse_T){
if (!sparse_T){
Tensor<> D(4,T.lens,*T.wrld);
D["abij"] += Ei["i"];
D["abij"] += Ei["j"];
D["abij"] -= Ea["a"];
D["abij"] -= Ea["b"];
Transform<> div([](double & b){ b=1./b; });
div(D["abij"]);
T["abij"] = T["abij"]*D["abij"];
} else {
Tensor<dpair> TD(4,sparse_T,T.lens,*T.wrld,Monoid<dpair,false>(dpair(0.0,0.0)));
TD["abij"] = Function<double,dpair>(
[](double d){
return dpair(d,0.0);
})(T["abij"]);
Transform<double,dpair> badd(
[](double d, dpair & p){
return p.b += d;
});
badd(Ei["i"],TD["abij"]);
badd(Ei["j"],TD["abij"]);
Transform<double,dpair> bsub(
[](double d, dpair & p){
return p.b -= d;
});
bsub(Ea["a"],TD["abij"]);
bsub(Ea["b"],TD["abij"]);
T["abij"] = Function<dpair,double>(
[](dpair p){
return p.a/p.b;
})(TD["abij"]);
}
}
double mp3(Tensor<> & Ea,
Tensor<> & Ei,
Tensor<> & Fab,
Tensor<> & Fij,
Tensor<> & Vabij,
Tensor<> & Vijab,
Tensor<> & Vabcd,
Tensor<> & Vijkl,
Tensor<> & Vaibj,
bool sparse_T){
Tensor<> T(4,sparse_T,Vabij.lens,*Vabij.wrld);
T["abij"] = Vabij["abij"];
divide_EaEi(Ea, Ei, T, sparse_T);
Tensor<> Z(4,Vabij.lens,*Vabij.wrld);
Z["abij"] = Vijab["ijab"];
Z["abij"] += Fab["af"]*T["fbij"];
Z["abij"] -= Fij["ni"]*T["abnj"];
Z["abij"] += 0.5*Vabcd["abef"]*T["efij"];
Z["abij"] += 0.5*Vijkl["mnij"]*T["abmn"];
Z["abij"] += Vaibj["amei"]*T["ebmj"];
divide_EaEi(Ea, Ei, Z, 0);
double MP3_energy = Z["abij"]*Vabij["abij"];
return MP3_energy;
}
int sparse_mp3(int nv, int no, World & dw, double sp=.8, bool test=1, int niter=0, bool bnd=1, bool bns=1, bool sparse_T=1){
int vvvv[] = {nv,nv,nv,nv};
int vovo[] = {nv,no,nv,no};
int vvoo[] = {nv,nv,no,no};
int oovv[] = {no,no,nv,nv};
int oooo[] = {no,no,no,no};
srand48(dw.rank);
Vector<> Ea(nv,dw);
Vector<> Ei(no,dw);
Ea.fill_random(1.0*nv*nv,2.0*nv*nv);
Ei.fill_random(-2.0*no*no,-1.0*no*no);
Matrix<> Fab(nv,nv,dw);
Matrix<> Fij(no,no,dw);
Fab.fill_random(-1.0,1.0);
Fij.fill_random(-1.0,1.0);
Tensor<> Vabij(4,vvoo,dw);
Tensor<> Vijab(4,oovv,dw);
Tensor<> Vabcd(4,vvvv,dw);
Tensor<> Vijkl(4,oooo,dw);
Tensor<> Vaibj(4,vovo,dw);
Vabij.fill_random(-1.0,1.0);
Vijab.fill_random(-1.0,1.0);
Vabcd.fill_random(-1.0,1.0);
Vijkl.fill_random(-1.0,1.0);
Vaibj.fill_random(-1.0,1.0);
Transform<> fltr([=](double & d){ if (fabs(d)<sp) d=0.0; });
fltr(Vabij["abij"]);
fltr(Vijab["ijab"]);
fltr(Vabcd["abcd"]);
fltr(Vijkl["ijkl"]);
fltr(Vaibj["aibj"]);
double dense_energy, sparse_energy;
if (test){
dense_energy = mp3(Ea, Ei, Fab, Fij, Vabij, Vijab, Vabcd, Vijkl, Vaibj, 0);
#ifndef TEST_SUITE
if (dw.rank == 0)
printf("Calculated MP3 energy %lf with dense integral tensors.\n",dense_energy);
#endif
} else
dense_energy = 0.0;
#ifndef TEST_SUITE
double min_time = DBL_MAX;
double max_time = 0.0;
double tot_time = 0.0;
double times[niter];
if (bnd){
if (dw.rank == 0){
printf("Starting %d benchmarking iterations of dense MP3...\n", niter);
}
Timer_epoch dmp3("dense MP3");
dmp3.begin();
for (int i=0; i<niter; i++){
double start_time = MPI_Wtime();
mp3(Ea, Ei, Fab, Fij, Vabij, Vijab, Vabcd, Vijkl, Vaibj, 0);
double end_time = MPI_Wtime();
double iter_time = end_time-start_time;
times[i] = iter_time;
tot_time += iter_time;
if (iter_time < min_time) min_time = iter_time;
if (iter_time > max_time) max_time = iter_time;
}
dmp3.end();
if (dw.rank == 0){
printf("Completed %d benchmarking iterations of dense MP3 (no=%d nv=%d sp=%lf).\n", niter, no, nv, sp);
printf("All iterations times: ");
for (int i=0; i<niter; i++){
printf("%lf ", times[i]);
}
printf("\n");
std::sort(times,times+niter);
printf("Dense MP3 (no=%d nv=%d sp=%lf p=%d) Min time = %lf, Avg time = %lf, Med time = %lf, Max time = %lf\n",no,nv,sp,dw.np,min_time,tot_time/niter, times[niter/2], max_time);
}
}
#endif
Vabcd.sparsify();
Vabij.sparsify();
Vabcd.sparsify();
Vijkl.sparsify();
Vaibj.sparsify();
if (test)
sparse_energy = mp3(Ea, Ei, Fab, Fij, Vabij, Vijab, Vabcd, Vijkl, Vaibj, sparse_T);
else
sparse_energy = 0.0;
bool pass;
if (test){
pass = fabs((dense_energy-sparse_energy)/dense_energy)<1.E-6;
if (Ea.wrld->rank == 0){
if (!sparse_T){
if (pass)
printf("{ third-order Moller-Plesset perturbation theory (MP3) using sparse*dense } passed \n");
else
printf("{ third-order Moller-Plesset perturbation theory (MP3) using sparse*dense } failed \n");
} else {
if (pass)
printf("{ third-order Moller-Plesset perturbation theory (MP3) using sparse*sparse } passed \n");
else
printf("{ third-order Moller-Plesset perturbation theory (MP3) using sparse*sparse } failed \n");
}
}
#ifndef TEST_SUITE
if (dw.rank == 0)
printf("Calcluated MP3 energy %lf with sparse integral tensors.\n",sparse_energy);
#endif
} else pass = 1;
#ifndef TEST_SUITE
if (bns){
if (dw.rank == 0){
printf("Starting %d benchmarking iterations of sparse MP3...\n", niter);
}
min_time = DBL_MAX;
max_time = 0.0;
tot_time = 0.0;
Timer_epoch smp3("sparse MP3");
smp3.begin();
for (int i=0; i<niter; i++){
double start_time = MPI_Wtime();
mp3(Ea, Ei, Fab, Fij, Vabij, Vijab, Vabcd, Vijkl, Vaibj, sparse_T);
double end_time = MPI_Wtime();
double iter_time = end_time-start_time;
#ifdef TUNE
CTF_int::update_all_models(dw.cdt.cm);
#endif
times[i] = iter_time;
tot_time += iter_time;
if (iter_time < min_time) min_time = iter_time;
if (iter_time > max_time) max_time = iter_time;
}
smp3.end();
if (dw.rank == 0){
printf("Completed %d benchmarking iterations of sparse MP3 (no=%d nv=%d).\n", niter, no, nv);
printf("All iterations times: ");
for (int i=0; i<niter; i++){
printf("%lf ", times[i]);
}
printf("\n");
std::sort(times,times+niter);
printf("Sparse MP3 (no=%d nv=%d sp=%lf p=%d spT=%d) Min time = %lf, Avg time = %lf, Med time = %lf, Max time = %lf\n",no,nv,sp,dw.np,sparse_T,min_time,tot_time/niter, times[niter/2], max_time);
}
}
#endif
return pass;
}
#ifndef TEST_SUITE
char* getCmdOption(char ** begin,
char ** end,
const std::string & option){
char ** itr = std::find(begin, end, option);
if (itr != end && ++itr != end){
return *itr;
}
return 0;
}
int main(int argc, char ** argv){
int rank, np, nv, no, pass, niter, bnd, bns, test;
bool sparse_T;
double sp;
int const in_num = argc;
char ** input_str = argv;
MPI_Init(&argc, &argv);
MPI_Comm_rank(MPI_COMM_WORLD, &rank);
MPI_Comm_size(MPI_COMM_WORLD, &np);
if (getCmdOption(input_str, input_str+in_num, "-nv")){
nv = atoi(getCmdOption(input_str, input_str+in_num, "-nv"));
if (nv < 0) nv = 7;
} else nv = 7;
if (getCmdOption(input_str, input_str+in_num, "-no")){
no = atoi(getCmdOption(input_str, input_str+in_num, "-no"));
if (no < 0) no = 7;
} else no = 7;
if (getCmdOption(input_str, input_str+in_num, "-sp")){
sp = atof(getCmdOption(input_str, input_str+in_num, "-sp"));
if (sp < 0.0 || sp > 1.0) sp = .8;
} else sp = .8;
if (getCmdOption(input_str, input_str+in_num, "-niter")){
niter = atof(getCmdOption(input_str, input_str+in_num, "-niter"));
if (niter < 0) niter = 10;
} else niter = 10;
if (getCmdOption(input_str, input_str+in_num, "-sparse_T")){
sparse_T = (bool)atoi(getCmdOption(input_str, input_str+in_num, "-sparse_T"));
} else sparse_T = 1;
if (getCmdOption(input_str, input_str+in_num, "-bnd")){
bnd = atoi(getCmdOption(input_str, input_str+in_num, "-bnd"));
if (bnd != 0 && bnd != 1) bnd = 0;
} else bnd = 0;
if (getCmdOption(input_str, input_str+in_num, "-bns")){
bns = atoi(getCmdOption(input_str, input_str+in_num, "-bns"));
if (bns != 0 && bns != 1) bns = 0;
} else bns = 0;
if (getCmdOption(input_str, input_str+in_num, "-test")){
test = atoi(getCmdOption(input_str, input_str+in_num, "-test"));
if (test != 0 && test != 1) test = 1;
} else test = 1;
if (rank == 0){
printf("Running sparse (%lf zeros) third-order Moller-Plesset perturbation theory (MP3) method on %d virtual and %d occupied orbitals and T sparsity turned to %d\n",sp,nv,no,sparse_T);
}
{
World dw;
pass = sparse_mp3(nv, no, dw, sp, test, niter, bnd, bns, sparse_T);
assert(pass);
}
MPI_Finalize();
return 0;
}
/**
* @}
* @}
*/
#endif