Exemple #1
0
    def __call__(self,
                 gradients=None,
                 force_constants=None,
                 small_change=False):
        self.checkUniverseVersion()
        args = [self.configuration.array]

        if ParticleProperties.isParticleProperty(gradients):
            args.append(gradients.array)
        elif isinstance(gradients, N.array_type):
            gradients = \
                 ParticleProperties.ParticleVector(self.universe, gradients)
            args.append(gradients.array)
        elif gradients:
            gradients = ParticleProperties.ParticleVector(self.universe, None)
            args.append(gradients.array)
        else:
            args.append(None)

        if ParticleProperties.isParticleProperty(force_constants):
            args.append(force_constants.array)
        elif isinstance(force_constants, N.array_type):
            force_constants = \
                ParticleProperties.SymmetricPairTensor(self.universe,
                                                       force_constants)
            args.append(force_constants.array)
        else:
            sparse_type = None
            try:
                from MMTK_forcefield import SparseForceConstants
                sparse_type = type(SparseForceConstants(2, 2))
            except ImportError:
                pass
            if isinstance(force_constants, sparse_type):
                args.append(force_constants)
            elif force_constants:
                force_constants = \
                    ParticleProperties.SymmetricPairTensor(self.universe, None)
                args.append(force_constants.array)
            else:
                args.append(None)

        args.append(small_change)
        self.universe.acquireReadStateLock()
        try:
            energy = apply(self.evaluator, tuple(args))
        finally:
            self.universe.releaseReadStateLock()
        if force_constants:
            return energy, gradients, force_constants
        elif gradients:
            return energy, gradients
        else:
            return energy
Exemple #2
0
    def __call__(self, gradients = None, force_constants = None,
		 small_change=0):
	self.checkUniverseVersion()
	args = [self.configuration.array]

	if ParticleProperties.isParticleProperty(gradients):
	    args.append(gradients.array)
	elif type(gradients) == Numeric.arraytype:
	    gradients = \
                 ParticleProperties.ParticleVector(self.universe, gradients)
	    args.append(gradients.array)
	elif gradients:
	    gradients = ParticleProperties.ParticleVector(self.universe, None)
	    args.append(gradients.array)
	else:
	    args.append(None)

	if ParticleProperties.isParticleProperty(force_constants):
	    args.append(force_constants.array)
	elif type(force_constants) == Numeric.arraytype:
	    force_constants = \
                ParticleProperties.SymmetricPairTensor(self.universe,
                                                       force_constants)
	    args.append(force_constants.array)
	else:
	    sparse_type = None
	    try:
		from MMTK_forcefield import SparseForceConstants
		sparse_type = type(SparseForceConstants(2, 2))
	    except ImportError: pass
	    if type(force_constants) == sparse_type:
		args.append(force_constants)
	    elif force_constants:
		force_constants = \
                    ParticleProperties.SymmetricPairTensor(self.universe, None)
		args.append(force_constants.array)
	    else:
		args.append(None)

	args.append(small_change)
        self.universe.acquireReadStateLock()
        try:
            energy = apply(self.evaluator, tuple(args))
        finally:
            self.universe.releaseReadStateLock()
	if force_constants:
	    return energy, gradients, force_constants
	elif gradients:
	    return energy, gradients
	else:
	    return energy
Exemple #3
0
 def __call__(self, vector, gradients = None):
     conf = self.universe.configuration()
     g = None
     if gradients is not None:
         if ParticleProperties.isParticleProperty(gradients):
             g = gradients
         elif isinstance(gradients, N.array_type):
             g = ParticleProperties.ParticleVector(self.universe, gradients)
         elif gradients:
             g = ParticleProperties.ParticleVector(self.universe)
     if g is None:
         g_array = None
     else:
         g_array = g.array
     l = deformation(conf.array, vector.array, self.pairs, g_array, None,
                     self.cutoff, self.fc_length, self.factor,
                     0, 1, self.version)
     if g is None:
         return l
     else:
         return l, g
Exemple #4
0
 def __call__(self, vector, gradients = None):
     conf = self.universe.configuration()
     g = None
     if gradients is not None:
         if ParticleProperties.isParticleProperty(gradients):
             g = gradients
         elif isinstance(gradients, N.array_type):
             g = ParticleProperties.ParticleVector(self.universe, gradients)
         elif gradients:
             g = ParticleProperties.ParticleVector(self.universe)
     if g is None:
         g_array = None
     else:
         g_array = g.array
     l = deformation(conf.array, vector.array, self.pairs, g_array, None,
                     self.cutoff, self.fc_length, self.factor,
                     0, 1, self.version)
     if g is None:
         return l
     else:
         return l, g
    def __call__(self, **options):
        # Process the keyword arguments
        self.setCallOptions(options)
        # Check if the universe has features not supported by the integrator
        Features.checkFeatures(self, self.universe)
        # Get the universe variables needed by the integrator
        configuration = self.universe.configuration()
        masses = self.universe.masses()
        velocities = self.universe.velocities()
        if velocities is None:
            raise ValueError("no velocities")

        # Get the friction coefficients. First check if a keyword argument
        # 'friction' was given to the integrator. Its value can be a
        # ParticleScalar or a plain number (used for all atoms). If no
        # such argument is given, collect the values of the attribute
        # 'friction' from all atoms (default is zero).
        try:
            friction = self.getOption('friction')
        except KeyError:
            friction = self.universe.getParticleScalar('friction')
        if not ParticleProperties.isParticleProperty(friction):
            var = ParticleProperties.ParticleScalar(self.universe)
            var.array[:] = friction
            friction = var

        # Construct a C evaluator object for the force field, using
        # the specified number of threads or the default value
        nt = self.getOption('threads')
        evaluator = self.universe.energyEvaluator(threads=nt).CEvaluator()

        # Run the C integrator
        MMTK_langevin.integrateLD(self.universe,
                                  configuration.array, velocities.array,
                                  masses.array, friction.array, evaluator,
                                  self.getOption('temperature'),
                                  self.getOption('delta_t'),
                                  self.getOption('steps'),
                                  self.getActions())