本文整理汇总了C++中SweepParams::get_n_iters方法的典型用法代码示例。如果您正苦于以下问题:C++ SweepParams::get_n_iters方法的具体用法?C++ SweepParams::get_n_iters怎么用?C++ SweepParams::get_n_iters使用的例子?那么恭喜您, 这里精选的方法代码示例或许可以为您提供帮助。您也可以进一步了解该方法所在类SweepParams
的用法示例。
在下文中一共展示了SweepParams::get_n_iters方法的6个代码示例,这些例子默认根据受欢迎程度排序。您可以为喜欢或者感觉有用的代码点赞,您的评价将有助于系统推荐出更棒的C++代码示例。
示例1: makeStateInfo
//Initialize stateinfo using the rotation matrices
void SpinAdapted::Sweep::InitializeStateInfo(SweepParams &sweepParams, const bool &forward, int currentstate)
{
sweepParams.set_sweep_parameters();
sweepParams.set_block_iter() = 0;
std::vector<int> sites;
int new_site, wave_site;
if (forward)
new_site = 0;
else
new_site = dmrginp.spinAdapted() ? dmrginp.last_site()-1 : dmrginp.last_site()/2-1;
if (dmrginp.spinAdapted())
sites.push_back(new_site);
else {
sites.push_back(2*new_site);
sites.push_back(2*new_site+1);
std::sort(sites.begin(), sites.end());
}
//only need statinfos
StateInfo stateInfo1; makeStateInfo(stateInfo1, new_site);
StateInfo::store(forward, sites, stateInfo1, currentstate);
for (; sweepParams.get_block_iter() < sweepParams.get_n_iters(); ) {
if (forward)
new_site++;
else
new_site--;
if (dmrginp.spinAdapted())
sites.push_back(new_site);
else {
sites.push_back(2*new_site);
sites.push_back(2*new_site+1);
std::sort(sites.begin(), sites.end());
}
StateInfo siteState, newState1;
makeStateInfo(siteState, new_site);
TensorProduct(stateInfo1, siteState, newState1, NO_PARTICLE_SPIN_NUMBER_CONSTRAINT);
newState1.CollectQuanta();
//make the newstate
std::vector<Matrix> rotation1;
LoadRotationMatrix (sites, rotation1, currentstate);
StateInfo renormState1;
SpinAdapted::StateInfo::transform_state(rotation1, newState1, renormState1);
StateInfo::store(forward, sites, renormState1, currentstate);
stateInfo1 = renormState1;
++sweepParams.set_block_iter();
}
}
示例2: BlockAndDecimate
void SweepTwopdm::BlockAndDecimate (SweepParams &sweepParams, SpinBlock& system, SpinBlock& newSystem, const bool &useSlater, const bool& dot_with_sys, int state)
{
//mcheck("at the start of block and decimate");
// figure out if we are going forward or backwards
dmrginp.guessgenT -> start();
bool forward = (system.get_sites() [0] == 0);
SpinBlock systemDot;
SpinBlock envDot;
int systemDotStart, systemDotEnd;
int systemDotSize = sweepParams.get_sys_add() - 1;
if (forward)
{
systemDotStart = dmrginp.spinAdapted() ? *system.get_sites().rbegin () + 1 : (*system.get_sites().rbegin ())/2 + 1 ;
systemDotEnd = systemDotStart + systemDotSize;
}
else
{
systemDotStart = dmrginp.spinAdapted() ? system.get_sites()[0] - 1 : (system.get_sites()[0])/2 - 1 ;
systemDotEnd = systemDotStart - systemDotSize;
}
vector<int> spindotsites(2);
spindotsites[0] = systemDotStart;
spindotsites[1] = systemDotEnd;
//if (useSlater) {
systemDot = SpinBlock(systemDotStart, systemDotEnd, system.get_integralIndex(), true);
//SpinBlock::store(true, systemDot.get_sites(), systemDot);
//}
//else
//SpinBlock::restore(true, spindotsites, systemDot);
SpinBlock environment, environmentDot, newEnvironment;
int environmentDotStart, environmentDotEnd, environmentStart, environmentEnd;
const int nexact = forward ? sweepParams.get_forward_starting_size() : sweepParams.get_backward_starting_size();
system.addAdditionalCompOps();
InitBlocks::InitNewSystemBlock(system, systemDot, newSystem, sweepParams.current_root(), sweepParams.current_root(), sweepParams.get_sys_add(), dmrginp.direct(), system.get_integralIndex(), DISTRIBUTED_STORAGE, true, true);
InitBlocks::InitNewEnvironmentBlock(environment, systemDot, newEnvironment, system, systemDot, sweepParams.current_root(), sweepParams.current_root(),
sweepParams.get_sys_add(), sweepParams.get_env_add(), forward, dmrginp.direct(),
sweepParams.get_onedot(), nexact, useSlater, system.get_integralIndex(), true, true, true);
SpinBlock big;
newSystem.set_loopblock(true);
system.set_loopblock(false);
newEnvironment.set_loopblock(false);
InitBlocks::InitBigBlock(newSystem, newEnvironment, big);
const int nroots = dmrginp.nroots();
std::vector<Wavefunction> solution(1);
DiagonalMatrix e;
GuessWave::guess_wavefunctions(solution[0], e, big, sweepParams.get_guesstype(), true, state, true, 0.0);
#ifndef SERIAL
mpi::communicator world;
mpi::broadcast(world, solution, 0);
#endif
std::vector<Matrix> rotateMatrix;
DensityMatrix tracedMatrix(newSystem.get_stateInfo());
tracedMatrix.allocate(newSystem.get_stateInfo());
tracedMatrix.makedensitymatrix(solution, big, std::vector<double>(1,1.0), 0.0, 0.0, false);
rotateMatrix.clear();
if (!mpigetrank())
double error = makeRotateMatrix(tracedMatrix, rotateMatrix, sweepParams.get_keep_states(), sweepParams.get_keep_qstates());
#ifndef SERIAL
mpi::broadcast(world,rotateMatrix,0);
#endif
#ifdef SERIAL
const int numprocs = 1;
#endif
#ifndef SERIAL
const int numprocs = world.size();
#endif
if (sweepParams.get_block_iter() == 0)
compute_twopdm_initial(solution, system, systemDot, newSystem, newEnvironment, big, numprocs, state);
compute_twopdm_sweep(solution, system, systemDot, newSystem, newEnvironment, big, numprocs, state);
if (sweepParams.get_block_iter() == sweepParams.get_n_iters() - 1)
compute_twopdm_final(solution, system, systemDot, newSystem, newEnvironment, big, numprocs, state);
SaveRotationMatrix (newSystem.get_sites(), rotateMatrix, state);
//for(int i=0;i<dmrginp.nroots();++i)
solution[0].SaveWavefunctionInfo (big.get_stateInfo(), big.get_leftBlock()->get_sites(), state);
newSystem.transform_operators(rotateMatrix);
}
示例3: do_one
double SweepTwopdm::do_one(SweepParams &sweepParams, const bool &warmUp, const bool &forward, const bool &restart, const int &restartSize, int state)
{
Timer sweeptimer;
int integralIndex = 0;
if (dmrginp.hamiltonian() == BCS) {
pout << "Two PDM with BCS calculations is not implemented" << endl;
exit(0);
}
pout.precision(12);
SpinBlock system;
const int nroots = dmrginp.nroots();
std::vector<double> finalEnergy(nroots,0.);
std::vector<double> finalEnergy_spins(nroots,0.);
double finalError = 0.;
sweepParams.set_sweep_parameters();
// a new renormalisation sweep routine
pout << ((forward) ? "\t\t\t Starting renormalisation sweep in forwards direction" : "\t\t\t Starting renormalisation sweep in backwards direction") << endl;
pout << "\t\t\t ============================================================================ " << endl;
InitBlocks::InitStartingBlock (system,forward, sweepParams.current_root(), sweepParams.current_root(), sweepParams.get_forward_starting_size(), sweepParams.get_backward_starting_size(), restartSize, restart, warmUp, integralIndex);
if(!restart)
sweepParams.set_block_iter() = 0;
pout << "\t\t\t Starting block is :: " << endl << system << endl;
if (!restart)
SpinBlock::store (forward, system.get_sites(), system, sweepParams.current_root(), sweepParams.current_root()); // if restart, just restoring an existing block --
sweepParams.savestate(forward, system.get_sites().size());
bool dot_with_sys = true;
array_4d<double> twopdm(2*dmrginp.last_site(), 2*dmrginp.last_site(), 2*dmrginp.last_site(), 2*dmrginp.last_site());
twopdm.Clear();
save_twopdm_binary(twopdm, state, state);
for (; sweepParams.get_block_iter() < sweepParams.get_n_iters(); )
{
pout << "\n\t\t\t Block Iteration :: " << sweepParams.get_block_iter() << endl;
pout << "\t\t\t ----------------------------" << endl;
if (forward)
p1out << "\t\t\t Current direction is :: Forwards " << endl;
else
p1out << "\t\t\t Current direction is :: Backwards " << endl;
//if (SHOW_MORE) pout << "system block" << endl << system << endl;
if (dmrginp.no_transform())
sweepParams.set_guesstype() = BASIC;
else if (!warmUp && sweepParams.get_block_iter() != 0)
sweepParams.set_guesstype() = TRANSFORM;
else if (!warmUp && sweepParams.get_block_iter() == 0 &&
((dmrginp.algorithm_method() == TWODOT_TO_ONEDOT && dmrginp.twodot_to_onedot_iter() != sweepParams.get_sweep_iter()) ||
dmrginp.algorithm_method() != TWODOT_TO_ONEDOT))
sweepParams.set_guesstype() = TRANSPOSE;
else
sweepParams.set_guesstype() = BASIC;
p1out << "\t\t\t Blocking and Decimating " << endl;
SpinBlock newSystem;
BlockAndDecimate (sweepParams, system, newSystem, warmUp, dot_with_sys, state);
for(int j=0;j<nroots;++j)
pout << "\t\t\t Total block energy for State [ " << j <<
" ] with " << sweepParams.get_keep_states()<<" :: " << sweepParams.get_lowest_energy()[j] <<endl;
finalEnergy_spins = ((sweepParams.get_lowest_energy()[0] < finalEnergy[0]) ? sweepParams.get_lowest_energy_spins() : finalEnergy_spins);
finalEnergy = ((sweepParams.get_lowest_energy()[0] < finalEnergy[0]) ? sweepParams.get_lowest_energy() : finalEnergy);
finalError = max(sweepParams.get_lowest_error(),finalError);
system = newSystem;
pout << system<<endl;
SpinBlock::store (forward, system.get_sites(), system, sweepParams.current_root(), sweepParams.current_root());
p1out << "\t\t\t saving state " << system.get_sites().size() << endl;
++sweepParams.set_block_iter();
//sweepParams.savestate(forward, system.get_sites().size());
}
//for(int j=0;j<nroots;++j)
{int j = state;
pout << "\t\t\t Finished Sweep with " << sweepParams.get_keep_states() << " states and sweep energy for State [ " << j
<< " ] with Spin [ " << dmrginp.molecule_quantum().get_s() << " ] :: " << finalEnergy[j] << endl;
}
pout << "\t\t\t Largest Error for Sweep with " << sweepParams.get_keep_states() << " states is " << finalError << endl;
pout << "\t\t\t ============================================================================ " << endl;
int i = state, j = state;
//for (int j=0; j<=i; j++) {
load_twopdm_binary(twopdm, i, j);
//calcenergy(twopdm, i);
save_twopdm_text(twopdm, i, j);
save_spatial_twopdm_text(twopdm, i, j);
save_spatial_twopdm_binary(twopdm, i, j);
// update the static number of iterations
//.........这里部分代码省略.........
示例4: InitializeOverlapSpinBlocks
//before you start optimizing each state you want to initalize all the overlap matrices
void Sweep::InitializeOverlapSpinBlocks(SweepParams &sweepParams, const bool &forward, int stateA, int stateB)
{
SpinBlock system;
sweepParams.set_sweep_parameters();
if (forward)
pout << "\t\t\t Starting sweep "<< sweepParams.set_sweep_iter()<<" in forwards direction"<<endl;
else
pout << "\t\t\t Starting sweep "<< sweepParams.set_sweep_iter()<<" in backwards direction" << endl;
pout << "\t\t\t ============================================================================ " << endl;
int restartSize = 0; bool restart = false, warmUp = false;
InitBlocks::InitStartingBlock (system,forward, stateA, stateB, sweepParams.get_forward_starting_size(), sweepParams.get_backward_starting_size(), restartSize, restart, warmUp);
sweepParams.set_block_iter() = 0;
if (dmrginp.outputlevel() > 0)
pout << "\t\t\t Starting block is :: " << endl << system << endl;
SpinBlock::store (forward, system.get_sites(), system, stateA, stateB); // if restart, just restoring an existing block --
sweepParams.savestate(forward, system.get_sites().size());
bool dot_with_sys = true;
vector<int> syssites = system.get_sites();
if (dmrginp.outputlevel() > 0)
mcheck("at the very start of sweep"); // just timer
for (; sweepParams.get_block_iter() < sweepParams.get_n_iters(); ) // get_n_iters() returns the number of blocking iterations needed in one sweep
{
pout << "\t\t\t Block Iteration :: " << sweepParams.get_block_iter() << endl;
pout << "\t\t\t ----------------------------" << endl;
if (dmrginp.outputlevel() > 0) {
if (forward) pout << "\t\t\t Current direction is :: Forwards " << endl;
else pout << "\t\t\t Current direction is :: Backwards " << endl;
}
SpinBlock systemDot, environmentDot;
int systemDotStart, systemDotEnd;
int systemDotSize = sweepParams.get_sys_add() - 1;
if (forward)
{
systemDotStart = dmrginp.spinAdapted() ? *system.get_sites().rbegin () + 1 : (*system.get_sites().rbegin ())/2 + 1 ;
systemDotEnd = systemDotStart + systemDotSize;
}
else
{
systemDotStart = dmrginp.spinAdapted() ? system.get_sites()[0] - 1 : (system.get_sites()[0])/2 - 1 ;
systemDotEnd = systemDotStart - systemDotSize;
}
systemDot = SpinBlock(systemDotStart, systemDotEnd, true);
SpinBlock newSystem; // new system after blocking and decimating
newSystem.initialise_op_array(OVERLAP, false);
newSystem.setstoragetype(DISTRIBUTED_STORAGE);
newSystem.BuildSumBlock (NO_PARTICLE_SPIN_NUMBER_CONSTRAINT, system, systemDot);
std::vector<Matrix> brarotateMatrix, ketrotateMatrix;
LoadRotationMatrix(newSystem.get_sites(), brarotateMatrix, stateA);
LoadRotationMatrix(newSystem.get_sites(), ketrotateMatrix, stateB);
newSystem.transform_operators(brarotateMatrix, ketrotateMatrix);
system = newSystem;
if (dmrginp.outputlevel() > 0){
pout << system<<endl;
}
SpinBlock::store (forward, system.get_sites(), system, stateA, stateB);
++sweepParams.set_block_iter();
sweepParams.savestate(forward, syssites.size());
if (dmrginp.outputlevel() > 0)
mcheck("at the end of sweep iteration");
}
pout << "\t\t\t ============================================================================ " << endl;
// update the static number of iterations
return ;
}
示例5: finalEnergy
double SpinAdapted::mps_nevpt::type1::do_one(SweepParams &sweepParams, const bool &warmUp, const bool &forward, const bool &restart, const int &restartSize, perturber& pb, int baseState)
{
int integralIndex = 0;
SpinBlock system;
system.nonactive_orb() = pb.orb();
const int nroots = dmrginp.nroots(sweepParams.get_sweep_iter());
std::vector<double> finalEnergy(nroots,-1.0e10);
std::vector<double> finalEnergy_spins(nroots,0.);
double finalError = 0.;
sweepParams.set_sweep_parameters();
// a new renormalisation sweep routine
if (forward)
if (dmrginp.outputlevel() > 0)
pout << "\t\t\t Starting sweep "<< sweepParams.set_sweep_iter()<<" in forwards direction"<<endl;
else
if (dmrginp.outputlevel() > 0)
{
pout << "\t\t\t Starting sweep "<< sweepParams.set_sweep_iter()<<" in backwards direction" << endl;
pout << "\t\t\t ============================================================================ " << endl;
}
InitBlocks::InitStartingBlock (system,forward, baseState, pb.wavenumber(), sweepParams.get_forward_starting_size(), sweepParams.get_backward_starting_size(), restartSize, restart, warmUp, integralIndex, pb.braquanta, pb.ketquanta);
if(!restart)
sweepParams.set_block_iter() = 0;
if (dmrginp.outputlevel() > 0)
pout << "\t\t\t Starting block is :: " << endl << system << endl;
SpinBlock::store (forward, system.get_sites(), system, pb.wavenumber(), baseState); // if restart, just restoring an existing block --
sweepParams.savestate(forward, system.get_sites().size());
bool dot_with_sys = true;
vector<int> syssites = system.get_sites();
if (restart)
{
if (forward && system.get_complementary_sites()[0] >= dmrginp.last_site()/2)
dot_with_sys = false;
if (!forward && system.get_sites()[0]-1 < dmrginp.last_site()/2)
dot_with_sys = false;
}
if (dmrginp.outputlevel() > 0)
mcheck("at the very start of sweep"); // just timer
for (; sweepParams.get_block_iter() < sweepParams.get_n_iters(); ) // get_n_iters() returns the number of blocking iterations needed in one sweep
{
if (dmrginp.outputlevel() > 0)
{
pout << "\t\t\t Block Iteration :: " << sweepParams.get_block_iter() << endl;
pout << "\t\t\t ----------------------------" << endl;
}
if (dmrginp.outputlevel() > 0) {
if (forward)
{
pout << "\t\t\t Current direction is :: Forwards " << endl;
}
else
{
pout << "\t\t\t Current direction is :: Backwards " << endl;
}
}
if (sweepParams.get_block_iter() != 0)
sweepParams.set_guesstype() = TRANSFORM;
else
sweepParams.set_guesstype() = TRANSPOSE;
if (dmrginp.outputlevel() > 0)
pout << "\t\t\t Blocking and Decimating " << endl;
SpinBlock newSystem; // new system after blocking and decimating
newSystem.nonactive_orb() = pb.orb();
//Need to substitute by:
// if (warmUp )
// Startup(sweepParams, system, newSystem, dot_with_sys, pb.wavenumber(), baseState);
// else {
// BlockDecimateAndCompress (sweepParams, system, newSystem, false, dot_with_sys, pb.wavenumber(), baseState);
// }
BlockDecimateAndCompress (sweepParams, system, newSystem, warmUp, dot_with_sys,pb, baseState);
//Need to substitute by?
system = newSystem;
if (dmrginp.outputlevel() > 0){
pout << system<<endl;
pout << system.get_braStateInfo()<<endl;
system.printOperatorSummary();
}
//system size is going to be less than environment size
if (forward && system.get_complementary_sites()[0] >= dmrginp.last_site()/2)
dot_with_sys = false;
if (!forward && system.get_sites()[0]-1 < dmrginp.last_site()/2)
dot_with_sys = false;
//.........这里部分代码省略.........
示例6: do_one
void SweepGenblock::do_one(SweepParams &sweepParams, const bool &forward, int stateA, int stateB)
{
Timer sweeptimer;
int integralIndex = 0;
SpinBlock system;
sweepParams.set_sweep_parameters();
// a new renormalisation sweep routine
pout << ((forward) ? "\t\t\t Starting renormalisation sweep in forwards direction" : "\t\t\t Starting renormalisation sweep in backwards direction") << endl;
pout << "\t\t\t ============================================================================ " << endl;
InitBlocks::InitStartingBlock (system,forward, stateA, stateB, sweepParams.get_forward_starting_size(), sweepParams.get_backward_starting_size(), 0, false, false, integralIndex);
sweepParams.set_block_iter() = 0;
p2out << "\t\t\t Starting block is :: " << endl << system << endl;
bool dot_with_sys = true;
for (; sweepParams.get_block_iter() < sweepParams.get_n_iters(); )
{
pout << "\n\t\t\t Block Iteration :: " << sweepParams.get_block_iter() << endl;
pout << "\t\t\t ----------------------------" << endl;
if (forward)
{ p1out << "\t\t\t Current direction is :: Forwards " << endl; }
else
{ p1out << "\t\t\t Current direction is :: Backwards " << endl; }
if (dmrginp.no_transform())
sweepParams.set_guesstype() = BASIC;
else if ( sweepParams.get_block_iter() != 0)
sweepParams.set_guesstype() = TRANSFORM;
else if ( sweepParams.get_block_iter() == 0 )
sweepParams.set_guesstype() = TRANSPOSE;
else
sweepParams.set_guesstype() = BASIC;
p1out << "\t\t\t Blocking and Decimating " << endl;
SpinBlock newSystem;
BlockAndDecimate (sweepParams, system, newSystem, false, dot_with_sys, stateA, stateB);
system = newSystem;
SpinBlock::store(forward, system.get_sites(), system, stateA, stateB);
//system size is going to be less than environment size
if (forward && system.get_complementary_sites()[0] >= dmrginp.last_site()/2)
dot_with_sys = false;
if (!forward && system.get_sites()[0]-1 < dmrginp.last_site()/2)
dot_with_sys = false;
++sweepParams.set_block_iter();
}
pout << "\t\t\t Finished Generate-Blocks Sweep. " << endl;
pout << "\t\t\t ============================================================================ " << endl;
// update the static number of iterations
++sweepParams.set_sweep_iter();
ecpu = sweeptimer.elapsedcputime(); ewall = sweeptimer.elapsedwalltime();
pout << "\t\t\t Elapsed Sweep CPU Time (seconds): " << setprecision(3) << ecpu << endl;
pout << "\t\t\t Elapsed Sweep Wall Time (seconds): " << setprecision(3) << ewall << endl;
}