def get_zero_backflow(rcut): from qmcpack_input import generate_transformation1, generate_transformation2 tr1 = generate_transformation1(['H'], rcut) tr2 = generate_transformation2([('u', 'u'), ('u', 'd')], rcut) from qmcpack_input import backflow, collection bf = backflow(transformations=collection([tr1, tr2])) return bf
def incorporate_result(self,result_name,result,sim): input = self.input system = self.system if result_name=='orbitals': if isinstance(sim,Pw2qmcpack) or isinstance(sim,Wfconvert): h5file = result.h5file wavefunction = input.get('wavefunction') if isinstance(wavefunction,collection): wavefunction = wavefunction.get_single('psi0') #end if wf = wavefunction if 'sposet_builder' in wf and wf.sposet_builder.type=='bspline': orb_elem = wf.sposet_builder elif 'sposet_builders' in wf and 'bspline' in wf.sposet_builders: orb_elem = wf.sposet_builders.bspline elif 'sposet_builders' in wf and 'einspline' in wf.sposet_builders: orb_elem = wf.sposet_builders.einspline elif 'determinantset' in wf and wf.determinantset.type in ('bspline','einspline'): orb_elem = wf.determinantset else: self.error('could not incorporate pw2qmcpack/wfconvert orbitals\nbspline sposet_builder and determinantset are both missing') #end if if 'href' in orb_elem and isinstance(orb_elem.href,str) and os.path.exists(orb_elem.href): # user specified h5 file for orbitals, bypass orbital dependency orb_elem.href = os.path.relpath(orb_elem.href,self.locdir) else: orb_elem.href = os.path.relpath(h5file,self.locdir) if system.structure.folded_structure!=None: orb_elem.tilematrix = array(system.structure.tmatrix) #end if #end if defs = obj( #twistnum = 0, meshfactor = 1.0 ) for var,val in defs.iteritems(): if not var in orb_elem: orb_elem[var] = val #end if #end for has_twist = 'twist' in orb_elem has_twistnum = 'twistnum' in orb_elem if not has_twist and not has_twistnum: orb_elem.twistnum = 0 #end if system = self.system structure = system.structure nkpoints = len(structure.kpoints) if nkpoints==0: self.error('system must have kpoints to assign twistnums') #end if if not os.path.exists(h5file): self.error('wavefunction file not found: \n'+h5file) #end if twistnums = range(len(structure.kpoints)) if self.should_twist_average: self.twist_average(twistnums) elif not has_twist and orb_elem.twistnum is None: orb_elem.twistnum = twistnums[0] #end if elif isinstance(sim,Sqd): h5file = os.path.join(result.dir,result.h5file) h5file = os.path.relpath(h5file,self.locdir) sqdxml_loc = os.path.join(result.dir,result.qmcfile) sqdxml = QmcpackInput(sqdxml_loc) #sqd sometimes puts the wrong ionic charge # rather than setting Z to the number of electrons # set it to the actual atomic number g = sqdxml.qmcsystem.particlesets.atom.group elem = g.name if not elem in periodic_table.elements: self.error(elem+' is not an element in the periodic table') #end if g.charge = periodic_table.elements[elem].atomic_number input = self.input s = input.simulation qsys_old = s.qmcsystem del s.qmcsystem s.qmcsystem = sqdxml.qmcsystem if 'jastrows' in qsys_old.wavefunction: s.qmcsystem.wavefunction.jastrows = qsys_old.wavefunction.jastrows for jastrow in s.qmcsystem.wavefunction.jastrows: if 'type' in jastrow: jtype = jastrow.type.lower().replace('-','_') if jtype=='one_body': jastrow.source = 'atom' #end if #end if #end for #end if s.qmcsystem.hamiltonian = hamiltonian( name='h0',type='generic',target='e', pairpots = [ pairpot(name='ElecElec',type='coulomb',source='e',target='e'), pairpot(name='Coulomb' ,type='coulomb',source='atom',target='e'), ] ) s.init = init(source='atom',target='e') abset = input.get('atomicbasisset') abset.href = h5file elif isinstance(sim,Convert4qmc): res = QmcpackInput(result.location) qs = input.simulation.qmcsystem oldwfn = qs.wavefunction newwfn = res.qmcsystem.wavefunction dset = newwfn.determinantset if 'jastrows' in newwfn: del newwfn.jastrows #end if if 'jastrows' in oldwfn: newwfn.jastrows = oldwfn.jastrows #end if if input.cusp_correction(): dset.cuspcorrection = True #end if if 'orbfile' in result: orb_h5file = result.orbfile if not os.path.exists(orb_h5file) and 'href' in dset: orb_h5file = os.path.join(sim.locdir,dset.href) #end if if not os.path.exists(orb_h5file): self.error('orbital h5 file from convert4qmc does not exist\nlocation checked: {}'.format(orb_h5file)) #end if orb_path = os.path.relpath(orb_h5file,self.locdir) dset.href = orb_path detlist = dset.get('detlist') if detlist is not None and 'href' in detlist: detlist.href = orb_path #end if #end if qs.wavefunction = newwfn else: self.error('incorporating orbitals from '+sim.__class__.__name__+' has not been implemented') #end if elif result_name=='jastrow': if isinstance(sim,Qmcpack): opt_file = result.opt_file opt = QmcpackInput(opt_file) wavefunction = input.get('wavefunction') optwf = opt.qmcsystem.wavefunction def process_jastrow(wf): if 'jastrow' in wf: js = [wf.jastrow] elif 'jastrows' in wf: js = wf.jastrows.values() else: js = [] #end if jd = dict() for j in js: jtype = j.type.lower().replace('-','_').replace(' ','_') jd[jtype] = j #end for return jd #end def process_jastrow if wavefunction==None: qs = input.get('qmcsystem') qs.wavefunction = optwf.copy() else: jold = process_jastrow(wavefunction) jopt = process_jastrow(optwf) jnew = list(jopt.values()) for jtype in jold.keys(): if not jtype in jopt: jnew.append(jold[jtype]) #end if #end for if len(jnew)==1: wavefunction.jastrow = jnew[0].copy() else: wavefunction.jastrows = collection(jnew) #end if #end if del optwf elif isinstance(sim,Sqd): wavefunction = input.get('wavefunction') jastrows = [] if 'jastrows' in wavefunction: for jastrow in wavefunction.jastrows: jname = jastrow.name if jname!='J1' and jname!='J2': jastrows.append(jastrow) #end if #end for del wavefunction.jastrows #end if ionps = input.get_ion_particlesets() if ionps is None or len(ionps)==0: self.error('ion particleset does not seem to exist') elif len(ionps)==1: ionps_name = list(ionps.keys())[0] else: self.error('multiple ion species not supported for atomic calculations') #end if jastrows.extend([ generate_jastrow('J1','bspline',8,result.rcut,iname=ionps_name,system=self.system), generate_jastrow('J2','pade',result.B) ]) wavefunction.jastrows = collection(jastrows) else: self.error('incorporating jastrow from '+sim.__class__.__name__+' has not been implemented') #end if elif result_name=='particles': if isinstance(sim,Convert4qmc): ptcl_file = result.location qi = QmcpackInput(ptcl_file) self.input.simulation.qmcsystem.particlesets = qi.qmcsystem.particlesets else: self.error('incorporating particles from '+sim.__class__.__name__+' has not been implemented') # end if elif result_name=='structure': relstruct = result.structure.copy() relstruct.change_units('B') self.system.structure = relstruct self.system.remove_folded() self.input.incorporate_system(self.system) elif result_name=='cuspcorr': ds = self.input.get('determinantset') ds.cuspcorrection = True try: # multideterminant ds.sposets['spo-up'].cuspinfo = os.path.relpath(result.spo_up_cusps,self.locdir) ds.sposets['spo-dn'].cuspinfo = os.path.relpath(result.spo_dn_cusps,self.locdir) except: # single determinant sd = ds.slaterdeterminant sd.determinants['updet'].cuspinfo = os.path.relpath(result.updet_cusps,self.locdir) sd.determinants['downdet'].cuspinfo = os.path.relpath(result.dndet_cusps,self.locdir) # end try elif result_name=='wavefunction': if not isinstance(sim,Qmcpack): self.error('incorporating wavefunction from '+sim.__class__.__name__+' has not been implemented') #end if print ' getting optimal wavefunction from: '+result.opt_file opt = QmcpackInput(result.opt_file) qs = input.get('qmcsystem') qs.wavefunction = opt.qmcsystem.wavefunction.copy() else: self.error('ability to incorporate result '+result_name+' has not been implemented')
def incorporate_result(self, result_name, result, sim): input = self.input system = self.system if result_name == 'orbitals': if isinstance(sim, Pw2qmcpack): h5file = result.h5file wavefunction = input.get('wavefunction') if isinstance(wavefunction, collection): wavefunction = wavefunction.get_single('psi0') #end if wf = wavefunction if 'sposet_builder' in wf and wf.sposet_builder.type == 'bspline': orb_elem = wf.sposet_builder elif 'sposet_builders' in wf and 'bspline' in wf.sposet_builders: orb_elem = wf.sposet_builders.bspline elif 'sposet_builders' in wf and 'einspline' in wf.sposet_builders: orb_elem = wf.sposet_builders.einspline elif 'determinantset' in wf and wf.determinantset.type in ( 'bspline', 'einspline'): orb_elem = wf.determinantset else: self.error( 'could not incorporate pw2qmcpack orbitals\nbspline sposet_builder and determinantset are both missing' ) #end if if 'href' in orb_elem and isinstance( orb_elem.href, str) and os.path.exists(orb_elem.href): # user specified h5 file for orbitals, bypass orbital dependency orb_elem.href = os.path.relpath(orb_elem.href, self.locdir) else: orb_elem.href = os.path.relpath(h5file, self.locdir) if system.structure.folded_structure != None: orb_elem.tilematrix = array(system.structure.tmatrix) #end if #end if defs = obj( #twistnum = 0, meshfactor=1.0) for var, val in defs.items(): if not var in orb_elem: orb_elem[var] = val #end if #end for has_twist = 'twist' in orb_elem has_twistnum = 'twistnum' in orb_elem if not has_twist and not has_twistnum: orb_elem.twistnum = 0 #end if system = self.system structure = system.structure nkpoints = len(structure.kpoints) if nkpoints == 0: self.error('system must have kpoints to assign twistnums') #end if if not os.path.exists(h5file): self.error('wavefunction file not found:\n' + h5file) #end if twistnums = list(range(len(structure.kpoints))) if self.should_twist_average: self.twist_average(twistnums) elif not has_twist and orb_elem.twistnum is None: orb_elem.twistnum = twistnums[0] #end if elif isinstance(sim, Convert4qmc): res = QmcpackInput(result.location) qs = input.simulation.qmcsystem oldwfn = qs.wavefunction newwfn = res.qmcsystem.wavefunction dset = newwfn.determinantset if 'jastrows' in newwfn: del newwfn.jastrows #end if if 'jastrows' in oldwfn: newwfn.jastrows = oldwfn.jastrows #end if if input.cusp_correction(): dset.cuspcorrection = True #end if if 'orbfile' in result: orb_h5file = result.orbfile if not os.path.exists(orb_h5file) and 'href' in dset: orb_h5file = os.path.join(sim.locdir, dset.href) #end if if not os.path.exists(orb_h5file): self.error( 'orbital h5 file from convert4qmc does not exist\nlocation checked: {}' .format(orb_h5file)) #end if orb_path = os.path.relpath(orb_h5file, self.locdir) dset.href = orb_path detlist = dset.get('detlist') if detlist is not None and 'href' in detlist: detlist.href = orb_path #end if #end if qs.wavefunction = newwfn else: self.error('incorporating orbitals from ' + sim.__class__.__name__ + ' has not been implemented') #end if elif result_name == 'jastrow': if isinstance(sim, Qmcpack): opt_file = result.opt_file opt = QmcpackInput(opt_file) wavefunction = input.get('wavefunction') optwf = opt.qmcsystem.wavefunction def process_jastrow(wf): if 'jastrow' in wf: js = [wf.jastrow] elif 'jastrows' in wf: js = list(wf.jastrows.values()) else: js = [] #end if jd = dict() for j in js: jtype = j.type.lower().replace('-', '_').replace(' ', '_') key = jtype # take care of multiple jastrows of the same type if key in jd: # use name to distinguish key += j.name if key in jd: # if still duplicate then error out msg = 'duplicate jastrow in ' + self.__class__.__name__ self.error(msg) #end if #end if jd[key] = j #end for return jd #end def process_jastrow if wavefunction == None: qs = input.get('qmcsystem') qs.wavefunction = optwf.copy() else: jold = process_jastrow(wavefunction) jopt = process_jastrow(optwf) jnew = list(jopt.values()) for jtype in jold.keys(): if not jtype in jopt: jnew.append(jold[jtype]) #end if #end for if len(jnew) == 1: wavefunction.jastrow = jnew[0].copy() else: wavefunction.jastrows = collection(jnew) #end if #end if del optwf elif result_name == 'particles': if isinstance(sim, Convert4qmc): ptcl_file = result.location qi = QmcpackInput(ptcl_file) self.input.simulation.qmcsystem.particlesets = qi.qmcsystem.particlesets else: self.error('incorporating particles from ' + sim.__class__.__name__ + ' has not been implemented') # end if elif result_name == 'structure': relstruct = result.structure.copy() relstruct.change_units('B') self.system.structure = relstruct self.system.remove_folded() self.input.incorporate_system(self.system) elif result_name == 'cuspcorr': ds = self.input.get('determinantset') ds.cuspcorrection = True try: # multideterminant ds.sposets['spo-up'].cuspinfo = os.path.relpath( result.spo_up_cusps, self.locdir) ds.sposets['spo-dn'].cuspinfo = os.path.relpath( result.spo_dn_cusps, self.locdir) except: # single determinant sd = ds.slaterdeterminant sd.determinants['updet'].cuspinfo = os.path.relpath( result.updet_cusps, self.locdir) sd.determinants['downdet'].cuspinfo = os.path.relpath( result.dndet_cusps, self.locdir) #end try elif result_name == 'wavefunction': if isinstance(sim, Qmcpack): opt = QmcpackInput(result.opt_file) qs = input.get('qmcsystem') qs.wavefunction = opt.qmcsystem.wavefunction.copy() elif isinstance(sim, PyscfToAfqmc): if not self.input.is_afqmc_input(): self.error( 'incorporating wavefunction from {} is only supported for AFQMC calculations' .format(sim.__class__.__name__)) #end if h5_file = os.path.relpath(result.h5_file, self.locdir) wfn = self.input.simulation.wavefunction ham = self.input.simulation.hamiltonian wfn.filename = h5_file wfn.filetype = 'hdf5' if 'filename' not in ham or ham.filename == 'MISSING.h5': ham.filename = h5_file ham.filetype = 'hdf5' #end if if 'xml' in result: xml = QmcpackInput(result.xml) info_new = xml.simulation.afqmcinfo.copy() info = self.input.simulation.afqmcinfo info.set_optional(**info_new) # override particular inputs set by default if 'generation_info' in input._metadata: g = input._metadata.generation_info if 'walker_type' not in g: walker_type = xml.get('walker_type') walkerset = input.get('walkerset') if walker_type is not None and walkerset is not None: walkerset.walker_type = walker_type #end if #end if #end if #end if else: self.error('incorporating wavefunction from ' + sim.__class__.__name__ + ' has not been implemented') #end if elif result_name == 'gc_occupation': from pwscf import Pwscf from qmcpack_converters import gcta_occupation if not isinstance(sim, Pw2qmcpack): msg = 'grand-canonical occupation require Pw2qmcpack' self.error(msg) #endif # step 1: extract Fermi energy for each spin from nscf nscf = None npwdep = 0 for dep in sim.dependencies: if isinstance(dep.sim, Pwscf): nscf = dep.sim npwdep += 1 if npwdep != 1: msg = 'need exactly 1 scf/nscf calculation for Fermi energy' msg += '\n found %d' % npwdep self.error(msg) #end if na = nscf.load_analyzer_image() Ef_list = na.fermi_energies # step 2: analyze ESH5 file for states below Fermi energy pa = sim.load_analyzer_image() if 'wfh5' not in pa: pa.analyze(Ef_list=Ef_list) sim.save_analyzer_image(pa) #end if # step 3: count the number of up/dn electrons at each supertwist s1 = self.system.structure ntwist = len(s1.kpoints) nelecs_at_twist = gcta_occupation(pa.wfh5, ntwist) self.nelecs_at_twist = nelecs_at_twist else: self.error('ability to incorporate result ' + result_name + ' has not been implemented')
def incorporate_result(self,result_name,result,sim): input = self.input system = self.system if result_name=='orbitals': if isinstance(sim,Pw2qmcpack) or isinstance(sim,Wfconvert): h5file = result.h5file wavefunction = input.get('wavefunction') if isinstance(wavefunction,collection): wavefunction = wavefunction.get_single('psi0') #end if wf = wavefunction if 'sposet_builder' in wf and wf.sposet_builder.type=='bspline': orb_elem = wf.sposet_builder elif 'sposet_builders' in wf and 'bspline' in wf.sposet_builders: orb_elem = wf.sposet_builders.bspline elif 'determinantset' in wf and wf.determinantset.type in ('bspline','einspline'): orb_elem = wf.determinantset else: self.error('could not incorporate pw2qmcpack/wfconvert orbitals\n bspline sposet_builder and determinantset are both missing') #end if orb_elem.href = os.path.relpath(h5file,self.locdir) if system.structure.folded_structure!=None: orb_elem.tilematrix = array(system.structure.tmatrix) #end if defs = obj( twistnum = 0, meshfactor = 1.0 ) for var,val in defs.iteritems(): if not var in orb_elem: orb_elem[var] = val #end if #end for system = self.system structure = system.structure nkpoints = len(structure.kpoints) if nkpoints==0: self.error('system must have kpoints to assign twistnums') #end if if not os.path.exists(h5file): self.error('wavefunction file not found: \n'+h5file) #end if twistnums = range(len(structure.kpoints)) if self.should_twist_average: self.twist_average(twistnums) elif orb_elem.twistnum is None: orb_elem.twistnum = twistnums[0] #end if elif isinstance(sim,Sqd): h5file = os.path.join(result.dir,result.h5file) h5file = os.path.relpath(h5file,self.locdir) sqdxml_loc = os.path.join(result.dir,result.qmcfile) sqdxml = QmcpackInput(sqdxml_loc) #sqd sometimes puts the wrong ionic charge # rather than setting Z to the number of electrons # set it to the actual atomic number g = sqdxml.qmcsystem.particlesets.atom.group elem = g.name if not elem in periodic_table.elements: self.error(elem+' is not an element in the periodic table') #end if g.charge = periodic_table.elements[elem].atomic_number input = self.input s = input.simulation qsys_old = s.qmcsystem del s.qmcsystem s.qmcsystem = sqdxml.qmcsystem if 'jastrows' in qsys_old.wavefunction: s.qmcsystem.wavefunction.jastrows = qsys_old.wavefunction.jastrows for jastrow in s.qmcsystem.wavefunction.jastrows: if 'type' in jastrow: jtype = jastrow.type.lower().replace('-','_') if jtype=='one_body': jastrow.source = 'atom' #end if #end if #end for #end if s.qmcsystem.hamiltonian = hamiltonian( name='h0',type='generic',target='e', pairpots = [ pairpot(name='ElecElec',type='coulomb',source='e',target='e'), pairpot(name='Coulomb' ,type='coulomb',source='atom',target='e'), ] ) s.init = init(source='atom',target='e') abset = input.get('atomicbasisset') abset.href = h5file else: self.error('incorporating orbitals from '+sim.__class__.__name__+' has not been implemented') #end if elif result_name=='jastrow': if isinstance(sim,Qmcpack): opt_file = result.opt_file opt = QmcpackInput(opt_file) wavefunction = input.get('wavefunction') optwf = opt.qmcsystem.wavefunction def process_jastrow(wf): if 'jastrow' in wf: js = [wf.jastrow] elif 'jastrows' in wf: js = wf.jastrows.values() else: js = [] #end if jd = dict() for j in js: jtype = j.type.lower().replace('-','_').replace(' ','_') jd[jtype] = j #end for return jd #end def process_jastrow if wavefunction==None: qs = input.get('qmcsystem') qs.wavefunction = optwf.copy() else: jold = process_jastrow(wavefunction) jopt = process_jastrow(optwf) jnew = list(jopt.values()) for jtype in jold.keys(): if not jtype in jopt: jnew.append(jold[jtype]) #end if #end for if len(jnew)==1: wavefunction.jastrow = jnew[0].copy() else: wavefunction.jastrows = collection(jnew) #end if #end if del optwf elif isinstance(sim,Sqd): wavefunction = input.get('wavefunction') jastrows = [] if 'jastrows' in wavefunction: for jastrow in wavefunction.jastrows: jname = jastrow.name if jname!='J1' and jname!='J2': jastrows.append(jastrow) #end if #end for del wavefunction.jastrows #end if ionps = input.get_ion_particlesets() if ionps is None or len(ionps)==0: self.error('ion particleset does not seem to exist') elif len(ionps)==1: ionps_name = list(ionps.keys())[0] else: self.error('multiple ion species not supported for atomic calculations') #end if jastrows.extend([ generate_jastrow('J1','bspline',8,result.rcut,iname=ionps_name,system=self.system), generate_jastrow('J2','pade',result.B) ]) wavefunction.jastrows = collection(jastrows) else: self.error('incorporating jastrow from '+sim.__class__.__name__+' has not been implemented') #end if elif result_name=='structure': structure = self.system.structure relstruct = result.structure structure.set( pos = relstruct.positions, atoms = relstruct.atoms ) self.input.incorporate_system(self.system) else: self.error('ability to incorporate result '+result_name+' has not been implemented')
def incorporate_result(self, result_name, result, sim): input = self.input system = self.system if result_name == "orbitals": if isinstance(sim, Pw2qmcpack) or isinstance(sim, Wfconvert): h5file = result.h5file dsold, wavefunction = input.get("determinantset", "wavefunction") if isinstance(wavefunction, collection): if "psi0" in wavefunction: wavefunction = wavefunction.psi0 else: wavefunction = wavefunction.list()[0] # end if # end if dsnew = dsold dsnew.set(type="einspline", href=os.path.relpath(h5file, self.locdir)) if system.structure.folded_structure != None: dsnew.tilematrix = array(system.structure.tmatrix) # end if defs = obj(twistnum=0, meshfactor=1.0, gpu=False) for var, val in defs.iteritems(): if not var in dsnew: dsnew[var] = val # end if # end for input.remove("determinantset") wavefunction.determinantset = dsnew system = self.system structure = system.structure nkpoints = len(structure.kpoints) if nkpoints == 0: self.error("system must have kpoints to assign twistnums") # end if if not os.path.exists(h5file): self.error("wavefunction file not found: \n" + h5file) # end if if "tilematrix" in system: dsnew.tilematrix = array(system.tilematrix) # end if twistnums = range(len(structure.kpoints)) if len(twistnums) > 1: self.twist_average(twistnums) else: dsnew.twistnum = twistnums[0] # end if elif isinstance(sim, Sqd): h5file = os.path.join(result.dir, result.h5file) h5file = os.path.relpath(h5file, self.locdir) sqdxml_loc = os.path.join(result.dir, result.qmcfile) sqdxml = QmcpackInput(sqdxml_loc) # sqd sometimes puts the wrong ionic charge # rather than setting Z to the number of electrons # set it to the actual atomic number g = sqdxml.qmcsystem.particlesets.atom.group elem = g.name if not elem in periodic_table.elements: self.error(elem + " is not an element in the periodic table") # end if g.charge = periodic_table.elements[elem].atomic_number input = self.input s = input.simulation qsys_old = s.qmcsystem del s.qmcsystem s.qmcsystem = sqdxml.qmcsystem if "jastrows" in qsys_old.wavefunction: s.qmcsystem.wavefunction.jastrows = qsys_old.wavefunction.jastrows for jastrow in s.qmcsystem.wavefunction.jastrows: if "type" in jastrow: jtype = jastrow.type.lower().replace("-", "_") if jtype == "one_body": jastrow.source = "atom" # end if # end if # end for # end if s.qmcsystem.hamiltonian = hamiltonian( name="h0", type="generic", target="e", pairpots=[ pairpot(name="ElecElec", type="coulomb", source="e", target="e"), pairpot(name="Coulomb", type="coulomb", source="atom", target="e"), ], ) s.init = init(source="atom", target="e") abset = input.get("atomicbasisset") abset.href = h5file else: self.error("incorporating orbitals from " + sim.__class__.__name__ + " has not been implemented") # end if elif result_name == "jastrow": if isinstance(sim, Qmcpack): opt_file = result.opt_file opt = QmcpackInput(opt_file) wavefunction = input.get("wavefunction") optwf = opt.qmcsystem.wavefunction def process_jastrow(wf): if "jastrow" in wf: js = [wf.jastrow] elif "jastrows" in wf: js = wf.jastrows.values() else: js = [] # end if jd = dict() for j in js: jtype = j.type.lower().replace("-", "_").replace(" ", "_") jd[jtype] = j # end for return jd # end def process_jastrow if wavefunction == None: qs = input.get("qmcsystem") qs.wavefunction = optwf.copy() else: jold = process_jastrow(wavefunction) jopt = process_jastrow(optwf) jnew = list(jopt.values()) for jtype in jold.keys(): if not jtype in jopt: jnew.append(jold[jtype]) # end if # end for if len(jnew) == 1: wavefunction.jastrow = jnew[0].copy() else: wavefunction.jastrows = collection(jnew) # end if # end if del optwf elif isinstance(sim, Sqd): wavefunction = input.get("wavefunction") jastrows = [] if "jastrows" in wavefunction: for jastrow in wavefunction.jastrows: jname = jastrow.name if jname != "J1" and jname != "J2": jastrows.append(jastrow) # end if # end for del wavefunction.jastrows # end if ionps = input.get_ion_particlesets() if ionps is None or len(ionps) == 0: self.error("ion particleset does not seem to exist") elif len(ionps) == 1: ionps_name = list(ionps.keys())[0] else: self.error("multiple ion species not supported for atomic calculations") # end if jastrows.extend( [ generate_jastrow("J1", "bspline", 8, result.rcut, iname=ionps_name, system=self.system), generate_jastrow("J2", "pade", result.B), ] ) wavefunction.jastrows = collection(jastrows) else: self.error("incorporating jastrow from " + sim.__class__.__name__ + " has not been implemented") # end if elif result_name == "structure": structure = self.system.structure relstruct = result.structure structure.set(pos=relstruct.positions, atoms=relstruct.atoms) self.input.incorporate_system(self.system) else: self.error("ability to incorporate result " + result_name + " has not been implemented")