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dchf.py
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dchf.py
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from pyscf import scf, mp, cc
from pyscf.lib import logger, diis
import numpy
import scipy
from scipy import cluster
import common
from warnings import warn
class HFLocalIntegralProvider(common.IntegralProvider):
def get_j(self, dm, atoms1, atoms2, atoms3=None, atoms4=None):
"""
Retrieves the J term in HF formalism (Coulomb repulsion).
Args:
dm (numpy.ndarray, dict): a dense or sparse density matrix;
atoms1 (list, tuple): a subset of atoms where the basis functions reside (column index);
atoms2 (list, tuple): a subset of atoms where the basis functions reside (row index);
atoms3 (list, tuple): a subset of atoms where the basis functions reside (first internal summation index);
atoms4 (list, tuple): a subset of atoms where the basis functions reside (second internal summation index);
Returns:
A matrix with Coulomb repulsion terms belonging to a given subset of atoms.
"""
return numpy.einsum("ijkl,kl->ij", self.get_eri(atoms1, atoms2, atoms3, atoms4), dm)
def get_k(self, dm, atoms1, atoms2, atoms3=None, atoms4=None):
"""
Retrieves the K term in HF formalism (exchange interaction).
Args:
dm (numpy.ndarray, dict): a dense or sparse density matrix;
atoms1 (list, tuple): a subset of atoms where the basis functions reside (column index);
atoms2 (list, tuple): a subset of atoms where the basis functions reside (row index);
atoms3 (list, tuple): a subset of atoms where the basis functions reside (first internal summation index);
atoms4 (list, tuple): a subset of atoms where the basis functions reside (second internal summation index);
Returns:
A matrix with Coulomb repulsion terms belonging to a given subset of atoms.
"""
return numpy.einsum("ijkl,jk->il", self.get_eri(atoms1, atoms3, atoms4, atoms2), dm)
def get_v_eff(self, *args, **kwargs):
"""
Retrieves the effective potential matrix terms in the HF formalism.
Args:
*args, **kwargs: see the description of `self.get_j` and `self.get_k`;
Returns:
An effective potential matrix terms belonging to a given subset of atoms.
"""
return self.get_j(*args, **kwargs) - 0.5*self.get_k(*args, **kwargs)
def get_fock(self, dm, atoms1, atoms2, **kwargs):
"""
Retrieves the Fock matrix terms.
Args:
dm (numpy.ndarray, dict): a dense or sparse density matrix;
atoms1 (list, tuple): a subset of atoms where the basis functions reside (column index);
atoms2 (list, tuple): a subset of atoms where the basis functions reside (row index);
**kwargs: see the description of `self.get_j` and `self.get_k`;
Returns:
Fock matrix terms belonging to a given subset of atoms.
"""
return self.get_hcore(atoms1, atoms2) + self.get_v_eff(dm, atoms1, atoms2, **kwargs)
def get_orbs(self, dm, atoms, **kwargs):
"""
Retrieves local HF orbitals and energies.
Args:
dm (numpy.ndarray, dict): a dense or sparse density matrix;
atoms (list, tuple): a subset of atoms where the basis functions of the iteration reside;
**kwargs: see the description of `self.get_j` and `self.get_k`;
Returns:
Fock matrix terms belonging to a given subset of atoms.
"""
fock = self.get_fock(dm, atoms, atoms, **kwargs)
ovlp = self.get_ovlp(atoms, atoms)
return scipy.linalg.eigh(fock, ovlp)
class Domain(object):
def __init__(self, atoms, provider, partition_matrix=None, core=None):
"""
Describes a domain composed of atoms.
Args:
atoms (list, tuple): a list of atoms of the domain;
provider (common.IntegralProvider): provider of integral values;
partition_matrix (numpy.ndarray): partition matrix for this domain;
core (list, tuple): atoms included in the core of this domain;
"""
self.atoms = tuple(atoms)
self.ao = provider.get_atom_basis(atoms)
self.shell_ranges = provider.shell_ranges(self.atoms)
n = len(self.ao)
if partition_matrix is None and core is None:
self.partition_matrix = numpy.ones((n, n), dtype=float)
elif partition_matrix is not None:
self.partition_matrix = partition_matrix
elif core is not None:
core_idx = provider.get_atom_basis(core, domain=atoms)
boundary_idx = provider.get_atom_basis(list(set(atoms) - set(core)), domain=atoms)
self.partition_matrix = numpy.zeros((n, n), dtype=float)
self.partition_matrix[numpy.ix_(core_idx, core_idx)] = 1.0
self.partition_matrix[numpy.ix_(core_idx, boundary_idx)] = 0.5
self.partition_matrix[numpy.ix_(boundary_idx, core_idx)] = 0.5
self.d2i = provider.get_block(self.atoms, self.atoms)
self.hcore = provider.get_hcore(self.atoms, self.atoms)
self.ovlp = provider.get_ovlp(self.atoms, self.atoms)
self.eri = provider.get_eri(self.atoms, self.atoms, self.atoms, self.atoms)
self.mol = provider.__mol__.copy()
self.mol._bas = numpy.concatenate(tuple(self.mol._bas[start:end] for start, end in self.shell_ranges), axis=0)
self.mol.nelectron = self.mol.atom_charges()[self.atoms, ].sum()
class DIISFockHook(object):
def __init__(self):
self.__diis__ = scf.diis.SCF_DIIS()
self.__diis__.space = 8
self.iterations = 0
def __call__(self, dchf):
self.iterations += 1
if self.iterations > 1:
return self.__diis__.update(dchf.ovlp, dchf.dm, dchf.fock)
else:
return dchf.fock
class DCHF(HFLocalIntegralProvider):
def __init__(self, mol, distribution_function=common.gaussian_distribution, temperature=30, eri_threshold=1e-12):
"""
An implementation of divide-conquer Hartree-Fock calculations. The domains are added via `self.add_domain`
method and stored inside `self.domains` list. Each list item contains all information on the domain including
the local space description and all relevant integral values.
Args:
mol (pyscf.mole.Mole): a Mole object to perform calculations;
distribution_function (func): a finite-temperature distribution function;
temperature (float): temperature of the distribution in Kelvin;
eri_threshold (float): threshold to discard electron repulsion integrals according to Cauchy-Schwartz upper
boundary;
"""
super(DCHF, self).__init__(mol)
self.distribution_function = distribution_function
self.__temperature__ = temperature * 8.621738e-5
self.eri_threshold = eri_threshold
self.domains = []
self.dm = None
self.fock = None
self.ovlp = None
self.hcore = None
self.hf_energy = None
self.e_tot = None
self.mu = None
self.convergence_history = []
self.eri_j = self.eri_k = None
def domains_erase(self):
"""
Erases all domain information.
"""
self.domains = []
def add_domain(self, domain, partition_matrix=None, core=None, insert_at=None):
"""
Adds a domain.
Args:
domain (list, tuple): a list of atoms included into this domain;
partition_matrix (numpy.ndarray): partition matrix for this domain;
core (list, tuple): atoms included in the core of this domain;
insert_at (int): insert domain into a specific position of `self.domains`'
"""
d = Domain(domain, self, partition_matrix=partition_matrix, core=core)
if d.mol.nelectron % 2 == 1:
warn("The number of electrons in the domain added is odd. Convergence may be difficult")
if insert_at is not None:
self.domains.insert(insert_at, d)
else:
self.domains.append(d)
def domains_pattern(self, n):
"""
Calculates a domain pattern.
Args:
n (int): the number of dimensions;
Returns:
An `n`-dimensional tensor masking the union of domains.
"""
result = numpy.zeros((len(self.__ao_ownership__),)*n)
for d in self.domains:
result[numpy.ix_(*((d.ao,)*n))] = True
return result
def build(self):
"""
Prepares matrixes.
"""
mask = self.domains_pattern(2)
# Overlap matrix
self.ovlp = self.get_ovlp(None, None) * mask
# Core matrix
self.hcore = self.get_hcore(None, None) * mask
# Density matrix
if self.dm is None:
self.dm = scf.hf.get_init_guess(self.__mol__)
self.dm *= mask
self.dm *= self.__mol__.nelectron / (self.dm*self.ovlp).sum()
# ERI
self.eri_j = {}
self.eri_k = {}
# Diagonal
for i, d in enumerate(self.domains):
self.eri_j[i, i] = d.eri
self.eri_k[i, i] = d.eri
# Off-diagonal
for i, d1 in enumerate(self.domains):
for j, d2 in enumerate(self.domains):
if j > i:
self.eri_j[i, j] = self.get_eri(d1.atoms, d1.atoms, d2.atoms, d2.atoms)
self.eri_j[j, i] = self.eri_j[i, j].transpose((2, 3, 0, 1))
self.eri_k[i, j] = self.get_eri(d1.atoms, d2.atoms, d2.atoms, d1.atoms)
self.eri_k[j, i] = self.eri_k[i, j].transpose((1, 0, 3, 2))
def domains_cover(self, r=True):
"""
Checks whether every atom is present in, at least, one domain.
Args:
r (bool): raises an exception if the return value is False;
Returns:
True if domains cover all atoms.
"""
all_atoms = set(range(self.__mol__.natm))
covered_atoms = set(numpy.concatenate(tuple(i.atoms for i in self.domains), axis=0))
result = all_atoms == covered_atoms
if not result and r:
raise ValueError("Atoms "+",".join(list(
"{:d}".format(i) for i in (all_atoms - covered_atoms)
))+" are not covered by any domain")
return result
def update_fock(self):
"""
Updates Fock matrix.
"""
self.fock = numpy.zeros_like(self.hcore)
for i, d in enumerate(self.domains):
self.fock[d.d2i] = self.hcore[d.d2i]
for j, d2 in enumerate(self.domains):
dm = self.dm[d2.d2i] * d2.partition_matrix
self.fock[d.d2i] += numpy.einsum("ijkl,kl->ij", self.eri_j[i, j], dm) -\
0.5*numpy.einsum("ijkl,jk->il", self.eri_k[i, j], dm)
def update_domain_eigs(self):
"""
Updates domains' eigenstates and eigenvalues.
"""
for i, d in enumerate(self.domains):
d.h = self.fock[d.d2i]
d.e, d.psi = scipy.linalg.eigh(d.h, d.ovlp)
d.weights = numpy.einsum("ij,kj,ik,ik->j", d.psi, d.psi, d.ovlp, d.partition_matrix)
def update_chemical_potential(self, threshold=1e-14):
"""
Calculates the chemical potential.
Args:
threshold (float): maximal allowed deviation from the expected electron number;
Returns:
The chemical potential.
"""
fock_energies = numpy.concatenate(list(i.e for i in self.domains), axis=0)
fock_energy_weights = numpy.concatenate(list(i.weights for i in self.domains), axis=0)
def n_electron(mu):
return (self.distribution_function(mu, self.__temperature__, fock_energies) * fock_energy_weights).sum()
top = fock_energies.max()
bottom = fock_energies.min()
for i in range(100):
middle = 0.5*(top+bottom)
n = n_electron(middle)
d = abs(top-bottom)
if d <= threshold:
self.mu = middle
return middle
elif n > self.__mol__.nelectron:
top = middle
else:
bottom = middle
raise ValueError("Failed to determine the chemical potential: error in chemical potential: {:.3e}".format(d))
def update_domain_dm(self):
"""
Updates density matrixes of domains.
"""
for domain in self.domains:
domain.occupations = self.distribution_function(self.mu, self.__temperature__, domain.e)
domain.dm = numpy.einsum("ij,j,kj->ik", domain.psi, domain.occupations, domain.psi)
def update_total_dm(self):
"""
Updates the total density matrix and the Hartree-Fock energy.
Returns:
The maximal deviation from the previous density matrix.
"""
old_dm = self.dm
self.dm = numpy.zeros_like(self.dm)
self.hf_energy = 0
for domain in self.domains:
masked_dm = domain.dm * domain.partition_matrix
self.dm[domain.d2i] += masked_dm
self.hf_energy += 0.5 * ((domain.h + domain.hcore) * masked_dm).sum()
self.e_tot = self.hf_energy + self.__mol__.energy_nuc()
return abs(self.dm-old_dm).max()
def kernel(self, tolerance=1e-6, maxiter=100, fock_hook="diis", domain_hook=None):
"""
Performs self-consistent iterations.
Args:
tolerance (float): density matrix convergence criterion;
maxiter (int): maximal number of iterations;
fock_hook (func): a hook called right after the Fock matrix was calculated. It is called with a single
argument, self, and should return a new Fock matrix. It is allowed to not return anything. A special
value "diis" stands for `pyscf.diis.DIIS.update` with an adjusted input;
domain_hook (func): a hook called right after the domains' eigenstates were updated. It is called with a
single argument, self. The return value is discarded;
Returns:
The converged energy value which is also stored as `self.hf_energy`.
"""
if fock_hook == "diis":
logger.info(self.__mol__, "Initializing DIIS ...")
fock_hook = DIISFockHook()
logger.info(self.__mol__, "Checking domain coverage ...")
self.domains_cover(r=True)
logger.info(self.__mol__, "Domains configuration:")
for d in self.domains:
logger.info(self.__mol__, " "+repr(list(d.atoms)))
logger.info(self.__mol__, "Calculating ERI blocks ...")
self.build()
self.convergence_history = []
logger.info(self.__mol__, "Running self-consistent calculation ...")
while True:
self.update_fock()
if fock_hook is not None:
result = fock_hook(self)
if result is not None:
self.fock = result
self.update_domain_eigs()
if domain_hook is not None:
domain_hook(self)
self.update_chemical_potential()
self.update_domain_dm()
delta = self.update_total_dm()
logger.info(self.__mol__, " E = {:.10f} delta = {:.3e} mu = {:.10f} q = {:.3e}".format(
self.e_tot,
delta,
self.mu,
self.__mol__.nelectron - (self.dm*self.ovlp).sum(),
))
logger.debug(self.__mol__, " mo_energy =\n{}".format(
repr(numpy.sort(numpy.concatenate(list(i.e for i in self.domains), axis=0))))
)
self.convergence_history.append(delta)
if delta < tolerance:
return self.hf_energy
if maxiter is not None and len(self.convergence_history) >= maxiter:
raise RuntimeError("The maximal number of iterations {:d} reached. The error {:.3e} is still above the requested tolerance of {:.3e}".format(
maxiter,
delta,
tolerance,
))
def energy_2(domains, w_occ, amplitude_calculator=None, with_t2=True):
"""
Calculates the second-order energy correction in domain setup.
Args:
domains (iterable): a list of domains;
w_occ (float): a parameter splitting the second-order energy contributions between occupied and virtual
molecular orbitals;
amplitude_calculator (func): calculator of second-order amplitudes. If None, then MP2 amplitudes are calculated;
with_t2 (bool): whether to save amplitudes;
Returns:
The energy correction.
"""
result = 0
if with_t2:
result_t2 = []
else:
result_t2 = None
for domain in domains:
occupations = domain.occupations
selection_occ = numpy.argwhere(occupations >= 1)[:, 0]
selection_virt = numpy.argwhere(occupations < 1)[:, 0]
psi = domain.psi
psi_occ = psi[:, selection_occ]
psi_virt = psi[:, selection_virt]
core_mask = numpy.diag(domain.partition_matrix)[:, numpy.newaxis]
psi_occ_core = psi_occ * core_mask
psi_virt_core = psi_virt * core_mask
__ov = common.transform(common.transform(domain.eri, psi_occ, axes=2), psi_virt, axes=3)
xvov = common.transform(common.transform(__ov, psi_occ_core, axes=0), psi_virt, axes=1)
oxov = common.transform(common.transform(__ov, psi_occ, axes=0), psi_virt_core, axes=1)
if amplitude_calculator is None:
e = domain.e
e_occ = e[selection_occ]
e_virt = e[selection_virt]
ovov = common.transform(common.transform(__ov, psi_occ, axes=0), psi_virt, axes=1)
t1 = None
t2 = ovov / (
e_occ[:, numpy.newaxis, numpy.newaxis, numpy.newaxis] -
e_virt[numpy.newaxis, :, numpy.newaxis, numpy.newaxis] +
e_occ[numpy.newaxis, numpy.newaxis, :, numpy.newaxis] -
e_virt[numpy.newaxis, numpy.newaxis, numpy.newaxis, :]
)
else:
t1, t2 = amplitude_calculator(domain)
amplitudes = 0
if t2 is not None:
amplitudes = t2
if t1 is not None:
amplitudes += numpy.einsum("ia,jb->iajb", t1, t1)
if amplitudes is not 0:
result += ((xvov * w_occ + oxov * (1.0 - w_occ)) * (2 * amplitudes - numpy.swapaxes(amplitudes, 0, 2))).sum()
if result_t2 is not None:
result_t2.append(amplitudes)
return result, result_t2
def pyscf_mp2_amplitude_calculator(domain):
"""
Calculates MP2 amplitudes in the domain.
Args:
domain (Domain): a domain to calculate at;
Returns:
MP2 amplitudes.
"""
mf = scf.RHF(domain.mol)
mf.build(domain.mol)
mf.mo_coeff = domain.psi
mf.mo_energy = domain.e
mf.mo_occ = domain.occupations
domain_mp2 = mp.MP2(mf)
domain_mp2.kernel()
return None, domain_mp2.t2.swapaxes(1, 2)
def pyscf_ccsd_amplitude_calculator(domain):
"""
Calculates CCSD amplitudes in the domain.
Args:
domain (Domain): a domain to calculate at;
Returns:
CCSD amplitudes.
"""
mf = scf.RHF(domain.mol)
mf.build(domain.mol)
mf.mo_coeff = domain.psi
mf.mo_energy = domain.e
mf.mo_occ = numpy.round(domain.occupations).astype(int)
domain_ccsd = cc.CCSD(mf)
domain_ccsd.kernel()
return domain_ccsd.t1, domain_ccsd.t2.swapaxes(1, 2)
class DCMP2(object):
def __init__(self, dchf, w_occ=1):
"""
An implementation of the divide-conquer MP2 on top of the divide-conquer Hartree-Fock.
Args:
dchf (DCHF): a completed divide-conquer Hartree-Fock calculation
w_occ (float): a parameter splitting the second-order energy contributions between occupied and virtual
molecular orbitals;
"""
self.mf = dchf
self.w_occ = w_occ
self.e2 = self.t2 = None
def kernel(self):
"""
Calculates DC-MP2 energy and amplitudes.
Returns:
DC-MP2 energy correction.
"""
self.e2, self.t2 = energy_2(self.mf.domains, self.w_occ)
return self.e2, self.t2
class DCCCSD(DCMP2):
def __init__(self, dchf, w_occ=1):
"""
An implementation of the divide-conquer CCSD on top of the divide-conquer Hartree-Fock.
Args:
dchf (DCHF): a completed divide-conquer Hartree-Fock calculation
w_occ (float): a parameter splitting the second-order energy contributions between occupied and virtual
molecular orbitals;
"""
DCMP2.__init__(self, dchf, w_occ=w_occ)
self.e1 = self.t1 = None
def kernel(self):
"""
Calculates DC-CCSD energy and amplitudes.
Returns:
DC-CCSD energy correction.
"""
self.e2, self.t2 = energy_2(self.mf.domains, self.w_occ, amplitude_calculator=pyscf_ccsd_amplitude_calculator)