コード例 #1
0
    def createSystem(self,
                     nonbondedMethod=ff.NoCutoff,
                     nonbondedCutoff=1.0 * u.nanometer,
                     constraints=None,
                     rigidWater=True,
                     implicitSolvent=None,
                     implicitSolventSaltConc=0.0 * (u.moles / u.liter),
                     implicitSolventKappa=None,
                     temperature=298.15 * u.kelvin,
                     soluteDielectric=1.0,
                     solventDielectric=78.5,
                     removeCMMotion=True,
                     hydrogenMass=None,
                     ewaldErrorTolerance=0.0005,
                     switchDistance=0.0 * u.nanometer,
                     gbsaModel='ACE'):
        """Construct an OpenMM System representing the topology described by this
        prmtop file.

        Parameters
        ----------
        nonbondedMethod : object=NoCutoff
            The method to use for nonbonded interactions.  Allowed values are
            NoCutoff, CutoffNonPeriodic, CutoffPeriodic, Ewald, PME, or LJPME.
        nonbondedCutoff : distance=1*nanometer
            The cutoff distance to use for nonbonded interactions
        constraints : object=None
            Specifies which bonds angles should be implemented with constraints.
            Allowed values are None, HBonds, AllBonds, or HAngles.
        rigidWater : boolean=True
            If true, water molecules will be fully rigid regardless of the value
            passed for the constraints argument
        implicitSolvent : object=None
            If not None, the implicit solvent model to use.  Allowed values are
            HCT, OBC1, OBC2, GBn, or GBn2.
        implicitSolventSaltConc : float=0.0*unit.moles/unit.liter
            The salt concentration for GB calculations (modelled as a debye
            screening parameter). It is converted to the debye length (kappa)
            using the provided temperature and solventDielectric
        temperature : float=300*kelvin
            Temperature of the system. Only used to compute the Debye length
            from implicitSolventSoltConc
        implicitSolventKappa : float units of 1/length
            If this value is set, implicitSolventSaltConc will be ignored.
        soluteDielectric : float=1.0
            The solute dielectric constant to use in the implicit solvent model.
        solventDielectric : float=78.5
            The solvent dielectric constant to use in the implicit solvent
            model.
        removeCMMotion : boolean=True
            If true, a CMMotionRemover will be added to the System
        hydrogenMass : mass=None
            The mass to use for hydrogen atoms bound to heavy atoms.  Any mass
            added to a hydrogen is subtracted from the heavy atom to keep their
            total mass the same.  If rigidWater is used to make water molecules
            rigid, then water hydrogens are not altered.
        ewaldErrorTolerance : float=0.0005
            The error tolerance to use if nonbondedMethod is Ewald, PME, or LJPME.
        switchDistance : float=0*nanometers
            The distance at which the potential energy switching function is
            turned on for Lennard-Jones interactions. If the switchDistance is 0
            or evaluates to boolean False, no switching function will be used.
            Values greater than nonbondedCutoff or less than 0 raise ValueError
        gbsaModel : str='ACE'
            The SA model used to model the nonpolar solvation component of GB
            implicit solvent models. If GB is active, this must be 'ACE' or None
            (the latter indicates no SA model will be used). Other values will
            result in a ValueError

        Returns
        -------
        System
            the newly created System
        """
        methodMap = {
            ff.NoCutoff: 'NoCutoff',
            ff.CutoffNonPeriodic: 'CutoffNonPeriodic',
            ff.CutoffPeriodic: 'CutoffPeriodic',
            ff.Ewald: 'Ewald',
            ff.PME: 'PME',
            ff.LJPME: 'LJPME'
        }
        if nonbondedMethod not in methodMap:
            raise ValueError('Illegal value for nonbonded method')
        if not self._prmtop.getIfBox() and nonbondedMethod in (
                ff.CutoffPeriodic, ff.Ewald, ff.PME, ff.LJPME):
            raise ValueError(
                'Illegal nonbonded method for a non-periodic system')
        constraintMap = {
            None: None,
            ff.HBonds: 'h-bonds',
            ff.AllBonds: 'all-bonds',
            ff.HAngles: 'h-angles'
        }
        if constraints is None:
            constraintString = None
        elif constraints in constraintMap:
            constraintString = constraintMap[constraints]
        else:
            raise ValueError('Illegal value for constraints')
        if implicitSolvent is None:
            implicitString = None
        elif implicitSolvent is HCT:
            implicitString = 'HCT'
        elif implicitSolvent is OBC1:
            implicitString = 'OBC1'
        elif implicitSolvent is OBC2:
            implicitString = 'OBC2'
        elif implicitSolvent is GBn:
            implicitString = 'GBn'
        elif implicitSolvent is GBn2:
            implicitString = 'GBn2'
        else:
            raise ValueError('Illegal value for implicit solvent model')
        # If implicitSolventKappa is None, compute it from the salt concentration
        if implicitSolvent is not None and implicitSolventKappa is None:
            if u.is_quantity(implicitSolventSaltConc):
                implicitSolventSaltConc = implicitSolventSaltConc.value_in_unit(
                    u.moles / u.liter)
            if u.is_quantity(temperature):
                temperature = temperature.value_in_unit(u.kelvin)
            # The constant is 1 / sqrt( epsilon_0 * kB / (2 * NA * q^2 * 1000) )
            # where NA is avogadro's number, epsilon_0 is the permittivity of
            # free space, q is the elementary charge (this number matches
            # Amber's kappa conversion factor)
            implicitSolventKappa = 50.33355 * sqrt(
                implicitSolventSaltConc / solventDielectric / temperature)
            # Multiply by 0.73 to account for ion exclusions, and multiply by 10
            # to convert to 1/nm from 1/angstroms
            implicitSolventKappa *= 7.3
        elif implicitSolvent is None:
            implicitSolventKappa = 0.0

        sys = amber_file_parser.readAmberSystem(
            self.topology,
            prmtop_loader=self._prmtop,
            shake=constraintString,
            nonbondedCutoff=nonbondedCutoff,
            nonbondedMethod=methodMap[nonbondedMethod],
            flexibleConstraints=False,
            gbmodel=implicitString,
            soluteDielectric=soluteDielectric,
            solventDielectric=solventDielectric,
            implicitSolventKappa=implicitSolventKappa,
            rigidWater=rigidWater,
            elements=self.elements,
            gbsaModel=gbsaModel)

        if hydrogenMass is not None:
            for atom1, atom2 in self.topology.bonds():
                if atom1.element == elem.hydrogen:
                    (atom1, atom2) = (atom2, atom1)
                if rigidWater and atom2.residue.name == 'HOH':
                    continue
                if atom2.element == elem.hydrogen and atom1.element not in (
                        elem.hydrogen, None):
                    transferMass = hydrogenMass - sys.getParticleMass(
                        atom2.index)
                    sys.setParticleMass(atom2.index, hydrogenMass)
                    sys.setParticleMass(
                        atom1.index,
                        sys.getParticleMass(atom1.index) - transferMass)
        for force in sys.getForces():
            if isinstance(force, mm.NonbondedForce):
                force.setEwaldErrorTolerance(ewaldErrorTolerance)
            if isinstance(force, (mm.NonbondedForce, mm.CustomNonbondedForce)):
                if switchDistance and nonbondedMethod is not ff.NoCutoff:
                    # make sure it's legal
                    if (_strip_optunit(switchDistance, u.nanometer) >=
                            _strip_optunit(nonbondedCutoff, u.nanometer)):
                        raise ValueError(
                            'switchDistance is too large compared '
                            'to the cutoff!')
                    if _strip_optunit(switchDistance, u.nanometer) < 0:
                        # Detects negatives for both Quantity and float
                        raise ValueError(
                            'switchDistance must be non-negative!')
                    force.setUseSwitchingFunction(True)
                    force.setSwitchingDistance(switchDistance)

        if removeCMMotion:
            sys.addForce(mm.CMMotionRemover())

        return sys
コード例 #2
0
ファイル: desmonddmsfile.py プロジェクト: z-gong/openmm
    def createSystem(self,
                     nonbondedMethod=ff.NoCutoff,
                     nonbondedCutoff=1.0 * nanometer,
                     ewaldErrorTolerance=0.0005,
                     removeCMMotion=True,
                     hydrogenMass=None,
                     OPLS=False,
                     implicitSolvent=None,
                     AGBNPVersion=1):
        """Construct an OpenMM System representing the topology described by this
        DMS file

        Parameters
        ----------
        nonbondedMethod : object=NoCutoff
            The method to use for nonbonded interactions.  Allowed values are
            NoCutoff, CutoffNonPeriodic, CutoffPeriodic, Ewald, PME, or LJPME.
        nonbondedCutoff : distance=1*nanometer
            The cutoff distance to use for nonbonded interactions
        ewaldErrorTolerance : float=0.0005
            The error tolerance to use if nonbondedMethod is Ewald, PME, or LJPME.
        removeCMMotion : boolean=True
            If true, a CMMotionRemover will be added to the System
        hydrogenMass : mass=None
            The mass to use for hydrogen atoms bound to heavy atoms.  Any mass
            added to a hydrogen is subtracted from the heavy atom to keep their
            total mass the same.
        OPLS : boolean=False
            If True, forces OPLS combining rules
        implicitSolvent: string=None
            If not None, creates implicit solvent force of the given name
            Allowed values are: HCT and 'AGBNP'
            (the corresponding tables must be present in the DMS file)
        AGBNPVersion: int=1
            AGBNP implicit solvent version
        """
        self._checkForUnsupportedTerms()
        sys = mm.System()

        # Build the box dimensions
        boxSize = self.topology.getUnitCellDimensions()
        if boxSize is not None:
            sys.setDefaultPeriodicBoxVectors(
                (boxSize[0], 0, 0), (0, boxSize[1], 0), (0, 0, boxSize[2]))
        elif nonbondedMethod in (ff.CutoffPeriodic, ff.Ewald, ff.PME,
                                 ff.LJPME):
            raise ValueError(
                'Illegal nonbonded method for a non-periodic system')

        # Create all of the particles
        for (fcounter, conn, tables, offset) in self._localVars():
            for mass in conn.execute('SELECT mass FROM particle ORDER BY id'):
                sys.addParticle(mass[0] * dalton)

        # Add all of the forces
        self._addBondsToSystem(sys)
        self._addAnglesToSystem(sys)
        self._addConstraintsToSystem(sys)
        self._addPeriodicTorsionsToSystem(sys, OPLS)
        self._addImproperHarmonicTorsionsToSystem(sys)
        self._addCMAPToSystem(sys)
        self._addVirtualSitesToSystem(sys)
        self._addPositionalHarmonicRestraints(sys)
        nb, cnb = self._addNonbondedForceToSystem(sys, OPLS)

        # Finish configuring the NonbondedForce.
        methodMap = {
            ff.NoCutoff: mm.NonbondedForce.NoCutoff,
            ff.CutoffNonPeriodic: mm.NonbondedForce.CutoffNonPeriodic,
            ff.CutoffPeriodic: mm.NonbondedForce.CutoffPeriodic,
            ff.Ewald: mm.NonbondedForce.Ewald,
            ff.PME: mm.NonbondedForce.PME,
            ff.LJPME: mm.NonbondedForce.LJPME
        }
        nb.setNonbondedMethod(methodMap[nonbondedMethod])
        nb.setCutoffDistance(nonbondedCutoff)
        nb.setEwaldErrorTolerance(ewaldErrorTolerance)
        if cnb is not None:
            nb.setUseDispersionCorrection(False)
            if nonbondedMethod in (ff.CutoffPeriodic, ff.Ewald, ff.PME,
                                   ff.LJPME):
                cnb.setNonbondedMethod(methodMap[ff.CutoffPeriodic])
                cnb.setCutoffDistance(nonbondedCutoff)
            elif nonbondedMethod == ff.CutoffNonPeriodic:
                cnb.setNonbondedMethod(methodMap[ff.CutoffNonPeriodic])
                cnb.setCutoffDistance(nonbondedCutoff)
            else:
                cnb.setNonbondedMethod(methodMap[ff.NoCutoff])
            cnb.setUseSwitchingFunction(False)
            cnb.setUseLongRangeCorrection(False)

        #add implicit solvent model.
        if implicitSolvent is not None:

            if not (implicitSolvent in (HCT, 'AGBNP', 'GVolSA', 'AGBNP3')):
                raise ValueError('Illegal implicit solvent method')

            if self._verbose:
                print('Adding implicit solvent ...')

            #with implicit solvent turn off native reaction field
            #However note that this does not affect the shifted Coulomb potential of the Nonbonded force
            #(it affects the only the energy, not the forces and equation of motion)
            nb.setReactionFieldDielectric(1.0)

            if implicitSolvent is HCT:
                gb_parms = self._get_gb_params()

                if gb_parms:
                    if self._verbose:
                        print('Adding HCT GB force ...')
                    gb = GBSAHCTForce(SA='ACE')
                    for i in range(len(gb_parms)):
                        gb.addParticle(list(gb_parms[i]))
                    gb.finalize()
                    sys.addForce(gb)
                else:
                    raise IOError("No HCT parameters found in DMS file")

            if implicitSolvent == 'AGBNP3':
                #load AGBNP3 plugin if available
                try:
                    from AGBNP3plugin import AGBNP3Force
                except ImportError:
                    raise NotImplementedError(
                        'AGBNP3 is not supported in this version')
                #sets up AGBNP3
                gb_parms = self._get_agbnp2_params()
                if gb_parms:
                    if self._verbose:
                        print('Adding AGBNP3 force ...')
                    gb = AGBNP3Force()
                    # add particles
                    for i in range(len(gb_parms)):
                        p = gb_parms[i]
                        gb.addParticle(p[0], p[1], p[2], p[3], p[4], p[5],
                                       p[6])
                    # connection table (from bonds)
                    self._add_agbnp2_ct(gb)
                    sys.addForce(gb)
                else:
                    raise IOError("No AGBNP parameters found in DMS file")

            if implicitSolvent == 'GVolSA':
                #implemented as AGBNP version 0
                implicitSolvent = 'AGBNP'
                AGBNPVersion = 0
                if self._verbose:
                    print('Using GVolSA')

            if implicitSolvent == 'AGBNP':
                #load AGBNP plugin if available
                try:
                    from AGBNPplugin import AGBNPForce
                except ImportError:
                    raise NotImplementedError(
                        'AGBNP is not supported in this version')
                #sets up AGBNP
                gb_parms = self._get_agbnp2_params()
                if gb_parms:
                    gb = AGBNPForce()
                    gb.setNonbondedMethod(methodMap[nonbondedMethod])
                    gb.setCutoffDistance(nonbondedCutoff)
                    gb.setVersion(AGBNPVersion)
                    if self._verbose:
                        print('Using AGBNP force version %d ...' %
                              AGBNPVersion)
                    # add particles
                    for i in range(len(gb_parms)):
                        [
                            radiusN, chargeN, gammaN, alphaN, hbtype, hbwN,
                            ishydrogenN
                        ] = gb_parms[i]
                        h_flag = ishydrogenN > 0
                        gb.addParticle(radiusN, gammaN, alphaN, chargeN,
                                       h_flag)
                    sys.addForce(gb)
                    self.gb_parms = gb_parms
                    self.agbnp = gb
                else:
                    raise IOError("No AGBNP parameters found in DMS file")

        # Adjust masses.
        if hydrogenMass is not None:
            for atom1, atom2 in self.topology.bonds():

                if atom1.element == hydrogen:
                    (atom1, atom2) = (atom2, atom1)
                if atom2.element == hydrogen and atom1.element not in (
                        hydrogen, None):
                    transferMass = hydrogenMass - sys.getParticleMass(
                        atom2.index)
                    sys.setParticleMass(atom2.index, hydrogenMass)
                    sys.setParticleMass(
                        atom1.index,
                        sys.getParticleMass(atom1.index) - transferMass)

        # Add a CMMotionRemover.
        if removeCMMotion:
            sys.addForce(mm.CMMotionRemover())

        return sys