Source code for psi4.driver.procrouting.empirical_dispersion

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import collections
from typing import Dict, List, Union

import numpy as np
from qcelemental.models import AtomicInput
import qcengine as qcng

from psi4 import core
from psi4.driver import p4util
from psi4.driver import driver_findif
from psi4.driver.p4util.exceptions import ValidationError

_engine_can_do = collections.OrderedDict([('libdisp', ['d1', 'd2', 'chg', 'das2009', 'das2010']),
                                          ('dftd3', ['d2', 'd3zero', 'd3bj', 'd3mzero', 'd3mbj']),
                                          ('nl', ['nl']),
                                          ('mp2d', ['dmp2']),
                                          ("dftd4", ["d4bjeeqatm"]),
                                        ]) # yapf: disable

_capable_engines_for_disp = collections.defaultdict(list)
for eng, disps in _engine_can_do.items():
    for disp in disps:
        _capable_engines_for_disp[disp].append(eng)


[docs]class EmpiricalDispersion(object): """Lightweight unification of empirical dispersion calculation modes. Attributes ---------- dashlevel : str {'d1', 'd2', 'd3zero', 'd3bj', 'd3mzero', 'd3mbj', 'chg', 'das2009', 'das2010', 'nl', 'dmp2', "d4bjeeqatm"} Name of dispersion correction to be applied. Resolved from `name_hint` and/or `level_hint` into a key of `empirical_dispersion_resources.dashcoeff`. dashparams : dict Complete set of parameter values defining the flexible parts of :py:attr:`dashlevel`. Number and parameter names vary by :py:attr:`dashlevel`. Resolved into a complete set (keys of dashcoeff[dashlevel]['default']) from `name_hint` and/or `dashcoeff_supplement` and/or user `param_tweaks`. fctldash : str If :py:attr:`dashparams` for :py:attr:`dashlevel` corresponds to a defined, named, untweaked "functional-dashlevel" set, then that functional. Otherwise, empty string. description : str Tagline for dispersion :py:attr:`dashlevel`. dashlevel_citation : str Literature reference for dispersion :py:attr:`dashlevel` in general, *not necessarily* for :py:attr:`dashparams`. dashparams_citation : str Literature reference for dispersion parameters, if :py:attr:`dashparams` corresponds to a defined, named, untweaked "functional-dashlevel" set with a citation. Otherwise, empty string. dashcoeff_supplement : dict See description in `qcengine.programs.empirical_dispersion_resources.from_arrays`. Used here to "bless" the dispersion definitions attached to the procedures/dft/<rung>_functionals-defined dictionaries as legit, non-custom, and of equal validity to `qcengine.programs.empirical_dispersion_resources.dashcoeff` itself for purposes of validating :py:attr:`fctldash`. engine : str {'libdisp', 'dftd3', 'nl', 'mp2d', "dftd4"} Compute engine for dispersion. One of Psi4's internal libdisp library, external Grimme or Beran projects, or nl. disp : Dispersion Only present for :py:attr:`engine` `=libdisp`. Psi4 class instance prepared to compute dispersion. ordered_params : list Fixed-order list of relevant parameters for :py:attr:`dashlevel`. Matches :rst:psivar:`DISPERSION CORRECTION ENERGY` ordering. Used for printing. Parameters ---------- name_hint Name of functional (func only, func & disp, or disp only) for which to compute dispersion (e.g., blyp, BLYP-D2, blyp-d3bj, blyp-d3(bj), hf+d). Any or all parameters initialized from ``dashcoeff[dashlevel][functional-without-dashlevel]`` or ``dashcoeff_supplement[dashlevel][functional-with-dashlevel]`` can be overwritten via `param_tweaks`. level_hint Name of dispersion correction to be applied (e.g., d, D2, d3(bj), das2010). Must be key in `dashcoeff` or "alias" or "formal" to one. param_tweaks Values for the same keys as `dashcoeff[dashlevel]['default']` (and same order if list) used to override any or all values initialized by `name_hint`. Extra parameters will error. engine Override which code computes dispersion. See above for allowed values. Really only relevant for -D2, which can be computed by libdisp or dftd3. """ def __init__(self, *, name_hint: str = None, level_hint: str = None, param_tweaks: Union[Dict, List] = None, engine: str = None, save_pairwise_disp=False): from .dft import dashcoeff_supplement self.dashcoeff_supplement = dashcoeff_supplement self.save_pairwise_disp = save_pairwise_disp resolved = qcng.programs.empirical_dispersion_resources.from_arrays( name_hint=name_hint, level_hint=level_hint, param_tweaks=param_tweaks, dashcoeff_supplement=self.dashcoeff_supplement) self.fctldash = resolved['fctldash'] self.dashlevel = resolved['dashlevel'] self.dashparams = resolved['dashparams'] self.description = qcng.programs.empirical_dispersion_resources.dashcoeff[self.dashlevel]['description'] self.ordered_params = qcng.programs.empirical_dispersion_resources.dashcoeff[self.dashlevel]['default'].keys() self.dashlevel_citation = qcng.programs.empirical_dispersion_resources.dashcoeff[self.dashlevel]['citation'] self.dashparams_citation = resolved['dashparams_citation'] if engine is None: self.engine = _capable_engines_for_disp[self.dashlevel][0] else: if self.dashlevel in _engine_can_do[engine]: self.engine = engine else: raise ValidationError("""This little engine ({}) can't ({})""".format(engine, self.dashlevel)) if self.engine == 'libdisp': self.disp = core.Dispersion.build(self.dashlevel, **resolved['dashparams'])
[docs] def print_out(self): """Format dispersion parameters of `self` for output file.""" text = [] text.append(" => {}: Empirical Dispersion <=".format( (self.fctldash.upper() if self.fctldash.upper() else 'Custom'))) text.append('') text.append(self.description) text.append(self.dashlevel_citation.rstrip()) if self.dashparams_citation: text.append(" Parametrisation from:{}".format(self.dashparams_citation.rstrip())) text.append('') for op in self.ordered_params: text.append(" %6s = %14.6f" % (op, self.dashparams[op])) text.append('\n') core.print_out('\n'.join(text))
[docs] def compute_energy(self, molecule: core.Molecule, wfn: core.Wavefunction = None) -> float: """Compute dispersion energy based on engine, dispersion level, and parameters in `self`. Parameters ---------- molecule System for which to compute empirical dispersion correction. wfn Location to set QCVariables Returns ------- float Dispersion energy [Eh]. Notes ----- :psivar:`DISPERSION CORRECTION ENERGY` Disp always set. Overridden in SCF finalization, but that only changes for "-3C" methods. :psivar:`fctl DISPERSION CORRECTION ENERGY` Set if :py:attr:`fctldash` nonempty. """ if self.engine in ['dftd3', 'mp2d', "dftd4"]: resi = AtomicInput( **{ 'driver': 'energy', 'model': { 'method': self.fctldash, 'basis': '(auto)', }, 'keywords': { 'level_hint': self.dashlevel, 'params_tweaks': self.dashparams, 'dashcoeff_supplement': self.dashcoeff_supplement, 'pair_resolved': self.save_pairwise_disp, 'verbose': 1, }, 'molecule': molecule.to_schema(dtype=2), 'provenance': p4util.provenance_stamp(__name__), }) jobrec = qcng.compute( resi, self.engine, raise_error=True, local_options={"scratch_directory": core.IOManager.shared_object().get_default_path()}) dashd_part = float(jobrec.extras['qcvars']['DISPERSION CORRECTION ENERGY']) if wfn is not None: for k, qca in jobrec.extras['qcvars'].items(): if ("CURRENT" not in k) and ("PAIRWISE" not in k): wfn.set_variable(k, float(qca) if isinstance(qca, str) else qca) # Pass along the pairwise dispersion decomposition if we need it if self.save_pairwise_disp is True: wfn.set_variable("PAIRWISE DISPERSION CORRECTION ANALYSIS", jobrec.extras['qcvars']["2-BODY PAIRWISE DISPERSION CORRECTION ANALYSIS"]) if self.fctldash in ['hf3c', 'pbeh3c']: jobrec = qcng.compute( resi, "gcp", raise_error=True, local_options={"scratch_directory": core.IOManager.shared_object().get_default_path()}) gcp_part = jobrec.return_result dashd_part += gcp_part return dashd_part else: ene = self.disp.compute_energy(molecule) core.set_variable('DISPERSION CORRECTION ENERGY', ene) if self.fctldash: core.set_variable(f"{self.fctldash} DISPERSION CORRECTION ENERGY", ene) return ene
[docs] def compute_gradient(self, molecule: core.Molecule, wfn: core.Wavefunction = None) -> core.Matrix: """Compute dispersion gradient based on engine, dispersion level, and parameters in `self`. Parameters ---------- molecule System for which to compute empirical dispersion correction. wfn Location to set QCVariables Returns ------- Matrix (nat, 3) dispersion gradient [Eh/a0]. """ if self.engine in ['dftd3', 'mp2d', "dftd4"]: resi = AtomicInput( **{ 'driver': 'gradient', 'model': { 'method': self.fctldash, 'basis': '(auto)', }, 'keywords': { 'level_hint': self.dashlevel, 'params_tweaks': self.dashparams, 'dashcoeff_supplement': self.dashcoeff_supplement, 'verbose': 1, }, 'molecule': molecule.to_schema(dtype=2), 'provenance': p4util.provenance_stamp(__name__), }) jobrec = qcng.compute( resi, self.engine, raise_error=True, local_options={"scratch_directory": core.IOManager.shared_object().get_default_path()}) dashd_part = core.Matrix.from_array(jobrec.extras['qcvars']['DISPERSION CORRECTION GRADIENT']) if wfn is not None: for k, qca in jobrec.extras['qcvars'].items(): if "CURRENT" not in k: wfn.set_variable(k, float(qca) if isinstance(qca, str) else qca) if self.fctldash in ['hf3c', 'pbeh3c']: jobrec = qcng.compute( resi, "gcp", raise_error=True, local_options={"scratch_directory": core.IOManager.shared_object().get_default_path()}) gcp_part = core.Matrix.from_array(jobrec.return_result) dashd_part.add(gcp_part) return dashd_part else: return self.disp.compute_gradient(molecule)
[docs] def compute_hessian(self, molecule: core.Molecule, wfn: core.Wavefunction = None) -> core.Matrix: """Compute dispersion Hessian based on engine, dispersion level, and parameters in `self`. Uses finite difference, as no dispersion engine has analytic second derivatives. Parameters ---------- molecule System for which to compute empirical dispersion correction. wfn Location to set QCVariables Returns ------- Matrix (3*nat, 3*nat) dispersion Hessian [Eh/a0/a0]. """ optstash = p4util.OptionsState(['PRINT'], ['PARENT_SYMMETRY']) core.set_global_option('PRINT', 0) core.print_out("\n\n Analytical Dispersion Hessians are not supported by any engine.\n") core.print_out(" Computing the Hessian through finite difference of gradients.\n\n") # Setup the molecule molclone = molecule.clone() molclone.reinterpret_coordentry(False) molclone.fix_orientation(True) molclone.fix_com(True) # Record undisplaced symmetry for projection of diplaced point groups core.set_global_option("PARENT_SYMMETRY", molecule.schoenflies_symbol()) findif_meta_dict = driver_findif.hessian_from_gradients_geometries(molclone, -1) for displacement in findif_meta_dict["displacements"].values(): geom_array = np.reshape(displacement["geometry"], (-1, 3)) molclone.set_geometry(core.Matrix.from_array(geom_array)) molclone.update_geometry() displacement["gradient"] = self.compute_gradient(molclone).np.ravel().tolist() H = driver_findif.assemble_hessian_from_gradients(findif_meta_dict, -1) if wfn is not None: wfn.set_variable('DISPERSION CORRECTION HESSIAN', H) optstash.restore() return core.Matrix.from_array(H)