194 lines
6.8 KiB
Python
194 lines
6.8 KiB
Python
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"""
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Provides interface n2v interface to Psi4
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"""
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from .engine import Engine
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import numpy as np
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from opt_einsum import contract
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try:
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import psi4
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psi4.set_options({"save_jk" : True})
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has_psi4 = True
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except ImportError:
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has_psi4 = False
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if has_psi4:
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from ..grid import Psi4Grider
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class Psi4Engine(Engine):
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"""
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Psi4 Engine Class
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"""
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def set_system(self, molecule, basis, ref='1', pbs='same', wfn=None):
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"""
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Initializes geometry and basis infromation
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Parameters
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----------
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molecule: psi4.core.Molecule
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Molecule of the system used
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basis: str
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Basis set of calculation
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ref: int
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Reference: Restricted -> 1
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Unrestricted -> 2
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pbs: str
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Basis set of potential used
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wfn : psi4.core.{RHF, UHF, RKS, UKS, Wavefunction, CCWavefuncion...}
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Psi4 wavefunction object
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"""
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self.mol = molecule
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#Assert units are in bohr
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# units = self.mol.to_schema(dtype='psi4')['units']
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# if units != "Bohr":
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# raise ValueError("Units need to be set in Bohr")
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self.basis_str = basis
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self.ref = ref
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self.pbs = pbs
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self.pbs_str = basis if pbs == 'same' else pbs
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self.nalpha = wfn.nalpha()
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self.nbeta = wfn.nbeta()
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self.wfn = wfn
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def initialize(self):
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"""
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Initializes basic objects required for the Psi4Engine
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"""
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self.basis = psi4.core.BasisSet.build( self.mol, key='BASIS', target=self.basis_str)
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self.pbs = psi4.core.BasisSet.build( self.mol, key='BASIS', target=self.pbs_str)
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self.nbf = self.basis.nbf()
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self.npbs = self.pbs.nbf()
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self.mints = psi4.core.MintsHelper( self.basis )
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self.jk = self.generate_jk()
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self.grid = Psi4Grider(self.mol, self.basis, self.ref)
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def get_T(self):
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"""Kinetic Potential in ao basis"""
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return np.array( self.mints.ao_kinetic() )
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def get_Tpbas(self):
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"""Kinetic Potential in pbs"""
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return np.array( self.mints.ao_kinetic(self.pbs, self.pbs) )
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def get_V(self):
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"""External potential in ao basis"""
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return np.array( self.mints.ao_potential() )
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def get_A(self):
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"""Inverse squared root of S matrix"""
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A = self.mints.ao_overlap()
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A.power( -0.5, 1e-16 )
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return np.array( A )
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def get_S(self):
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"""Overlap matrix in AO basis"""
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return np.array( self.mints.ao_overlap() )
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def get_S3(self):
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"""3 Orbitals Overlap matrix in AO basis"""
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return np.array( self.mints.ao_3coverlap(self.basis,self.basis,self.pbs) )
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def get_S4(self):
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"""
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Calculates four overlap integral with Density Fitting method.
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S4_{ijkl} = \int dr \phi_i(r)*\phi_j(r)*\phi_k(r)*\phi_l(r)
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Parameters
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----------
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wfn: psi4.core.Wavefunction
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Wavefunction object of moleculep
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Return
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------
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S4
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"""
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print(f"4-AO-Overlap tensor will take about {self.nbf **4 / 8 * 1e-9:f} GB.")
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aux_basis = psi4.core.BasisSet.build(self.mol, "DF_BASIS_SCF", "", "JKFIT", self.basis_str)
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S_Pmn = np.squeeze(self.mints.ao_3coverlap(aux_basis, self.basis, self.basis ))
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S_PQ = np.array(self.mints.ao_overlap(aux_basis, aux_basis))
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S_PQinv = np.linalg.pinv(S_PQ, rcond=1e-9)
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S4 = contract('Pmn,PQ,Qrs->mnrs', S_Pmn, S_PQinv, S_Pmn)
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return S4
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def generate_jk(self, gen_K=False):
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"""
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Creates jk object for generation of Coulomb and Exchange matrices
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1.0e9 B -> 1.0 GB
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"""
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jk = psi4.core.JK.build(self.basis)
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memory = int(jk.memory_estimate() * 1.1)
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jk.set_memory(int(memory))
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# added by Ehsan
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# .set_do_K(gen_K = False) determines if exchane matrices should be calculated or not
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jk.set_do_K(gen_K)
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jk.initialize()
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#print("jk: ", jk)
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return jk
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def compute_hartree(self, Cocc_a, Cocc_b):
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"""
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Generates Coulomb and Exchange matrices from occupied orbitals
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"""
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Cocc_a = psi4.core.Matrix.from_array(Cocc_a)
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Cocc_b = psi4.core.Matrix.from_array(Cocc_b)
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self.jk.C_left_add(Cocc_a)
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self.jk.C_left_add(Cocc_b)
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self.jk.compute()
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self.jk.C_clear()
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J = (np.array(self.jk.J()[0]), np.array(self.jk.J()[1]))
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return J
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def hartree_NO(self, Dta):
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"""
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Computes Hartree potential in AO basis from Natural Orbitals
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"""
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if self.wfn is None:
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raise ValueError('Please provide a wfn object to the Inverter, i.e., Inverter.eng = wfn')
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if type(self.wfn) == psi4.core.CCWavefunction:
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C_NO = psi4.core.Matrix(self.nbf, self.nbf)
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eigs_NO = psi4.core.Vector(self.nbf)
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self.wfn.Da().diagonalize( C_NO, eigs_NO, psi4.core.DiagonalizeOrder.Descending )
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occ = np.sqrt( np.array(eigs_NO) )
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new_CA = occ * np.array(C_NO)
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assert np.allclose( new_CA @ new_CA.T, Dta )
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if self.ref == 1:
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new_CB = np.copy( new_CA )
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else:
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self.wfn.Db().diagonalize( C_NO, eigs_NO, psi4.core.DiagonalizeOrder.Descending )
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occ_b = np.sqrt( np.array( eigs_NO ) )
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new_CB = occ_b * np.array( C_NO )
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J0 = self.compute_hartree(new_CA, new_CB)
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return J0
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def run_single_point(self, mol, basis, method):
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"""
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Run a standard energy calculation
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"""
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wfn_temp = psi4.energy(init+"/" + self.basis_str,
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molecule=self.mol,
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return_wfn=True)[1]
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if self.ref == 1:
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D = np.array(wfn_temp.Da()) + np.array(wfn_temp.Db())
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C = np.array(wfn_temp.Ca())
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e = np.array(wfn_temp.epsilon_a())
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else:
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D = np.stack( (np.array(wfn_temp.Da()), np.array(wfn_temp.Db())) )
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C = np.stack( (np.array(wfn_temp.Ca()), np.array(wfn_temp.Cb())) )
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e = np.stack( (np.array(wfn_temp.epsilon_a()), np.array(wfn_temp.epsilon_b())) )
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return D, C, e
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