# Copyright 2021-2023 @ Shenzhen Bay Laboratory &
# Peking University &
# Huawei Technologies Co., Ltd
#
# This code is a part of MindSPONGE:
# MindSpore Simulation Package tOwards Next Generation molecular modelling.
#
# MindSPONGE is open-source software based on the AI-framework:
# MindSpore (https://www.mindspore.cn/)
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
# ============================================================================
"""Space updater"""
from typing import Union, List
from numpy import ndarray
from mindspore import Tensor
from mindspore.nn.optim.optimizer import opt_init_args_register
from . import Updater
from ..system import Molecule
from ..control.controller import Controller
from ..control.integrator import Integrator, get_integrator
from ..control.thermostat import Thermostat, get_thermostat
from ..control.barostat import Barostat, get_barostat
from ..control.constraint import Constraint, get_constraint
from ..function import get_arguments
[文档]class UpdaterMD(Updater):
r"""
A updater for molecular dynamics (MD) simulation, which is the subclass of `Updater`.
UpdaterMD uses four different `Controllers` to control the different
variables in the simulation process. The `integrator` is used for update
the atomic coordinates and velocities, the `thermostat` is used for
temperature coupling, the `barostat` is used for pressure coupling, and
the `constraint` is used for bond constraint.
Args:
system (:class:`sponge.system.Molecule`): Simulation system.
time_step (float, optional): Time step. Default: 1e-3.
velocity (Union[Tensor, ndarray, List[float]], optional): Array of atomic velocity.
The shape of array is :math:`(A, D)` or :math:`(B, A, D)`.
Here :math:`B` is the number of walkers in simulation,
:math:`A` is the number of atoms,
:math:`D` is the spatial dimension of the simulation system, which is usually 3.
Data type is float. Default: ``None``.
temperature (float, optional): Reference temperature for coupling.
Only valid if `thermostat` is set to type `str`. Default: ``None``.
pressure (float, optional): Reference pressure for temperature coupling.
Only valid if `barostat` is set to type `str`. Default: ``None``.
integrator (Union[`sponge.control.Integrator`, str], optional): Integrator
for MD simulation.
It can be an object of `Integrator` or the `str` of an integrator name.
Default: 'leap_frog'
thermostat (Union[`sponge.control.Thermostat`, str], optional): Thermostat
for temperature coupling.
It can be an object of `sponge.control.Thermostat`
or the `str` of a thermostat name.
If a `str` is given, then it will only valid if the `temperature` is not ``None``.
Default: 'berendsen'
barostat (Union[`sponge.control.Barostat`, str], optional): Barostat
for pressure coupling.
It can be an object of `Barostat` or the `str` of a barostat name.
If a `str` is given, then it will only valid if the `pressure` is not `None`.
Default: ``'berendsen'``.
constraint (Union[`sponge.control.Constraint`, List[`sponge.control.Constraint`]], optional):
Constraint controller(s) for bond constraint. Default: ``None``.
controller (Union[:class:`sponge.control.Controller`, List[:class:`sponge.control.Controller`]], optional):
Other controller(s). It will work after the four specific
controllers (integrator, thermostat, barostat and constraint).
Default: ``None``.
weight_decay (float, optional): An value for the weight decay. Default: ``0.0``.
loss_scale (float, optional): A value for the loss scale. Default: ``1.0``.
Inputs:
- **energy** (Tensor) - Total potential energy of the simulation system.
Tensor of shape :math:`(B, 1)`.
Here :math:`B` is the batch size, i.e. the number of walkers in simulation.
Data type is float.
- **force** (Tensor) - Force on each atoms of the simulation system.
Tensor of shape :math:`(B, A, D)`.
Here :math:`A` is the number of atoms,
:math:`D` is the spatial dimension of the simulation system, which is usually 3.
- **virial** (Tensor) - Virial tensor of the simulation system.
Tensor of shape :math:`(B, D, D)`.
Data type is float. Default: ``None``.
Outputs:
- **success** (bool) - whether successfully finish the current optimization step and move to next step.
Supported Platforms:
``Ascend`` ``GPU``
Examples:
>>> from sponge import UpdaterMD, Molecule
>>> from mindspore import Tensor
>>> system = Molecule(template='water.tip3p.yaml')
>>> velocity = Tensor([[0.1008,0.,0.],[-0.8,0.,0.],[-0.8,0.,0.]])
>>> opt = UpdaterMD(system=system,
... time_step=1e-3,
... velocity=velocity,
... integrator='leap_frog',
... temperature=None,
... thermostat=None)
>>> # In actual usage, the energy and force are calculated by the
>>> # potential cell or the neural network model
>>> print(opt.coordinate.value())
>>> # [[[ 0. 0. 0. ]
>>> # [ 0.07907964 0.06120793 0. ]
>>> # [-0.07907964 0.06120793 0. ]]]
>>> force = Tensor([[0.,0.,0.],[0.,0.,0.],[0.,0.,0.]])
>>> opt(energy=Tensor([0.0]), force=force)
>>> print(opt.coordinate.value())
>>> # [[[ 0.0001008 0. 0. ]
>>> # [ 0.07827964 0.06120793 0. ]
>>> # [-0.07987964 0.06120793 0. ]]]
"""
@opt_init_args_register
def __init__(self,
system: Molecule,
time_step: float = 1e-3,
velocity: Union[Tensor, ndarray, List[float]] = None,
temperature: float = None,
pressure: float = None,
integrator: Union[Integrator, str] = 'leap_frog',
thermostat: Union[Thermostat, str] = 'berendsen',
barostat: Union[Barostat, str] = 'berendsen',
constraint: Union[Constraint, List[Constraint], str] = None,
controller: Union[Controller, List[Controller]] = None,
weight_decay: float = 0.0,
loss_scale: float = 1.0,
**kwargs,
):
super().__init__(
system=system,
controller=controller,
time_step=time_step,
velocity=velocity,
weight_decay=weight_decay,
loss_scale=loss_scale,
)
self._kwargs = get_arguments(locals(), kwargs)
self._kwargs.pop('velocity')
self.integrator: Integrator = get_integrator(integrator, self.system)
self.integrator.set_time_step(self.time_step)
self.constraint: Constraint = None
self.set_constraint(constraint)
self.thermostat: Thermostat = None
self.set_thermostat(thermostat, temperature)
self.barostat: Barostat = None
self.set_barostat(barostat, pressure)
@property
def ref_temp(self):
r"""
Reference temperature for thermostat.
Returns:
float, reference temperature for thermostat.
"""
if self.thermostat is None:
return None
return self.thermostat.temperature
@property
def ref_press(self):
r"""
Reference pressure for barostat.
Returns:
float, reference pressure for barostat.
"""
if self.barostat is None:
return None
return self.barostat.pressure
[文档] def set_temperature(self, temperature: float):
r"""
Set reference temperature for thermostat
Args:
temperature (float): Reference temperature for thermostat.
"""
if self.thermostat is not None:
return self.thermostat.set_temperature(temperature)
return None
[文档] def set_pressure(self, pressure: float):
r"""
Set reference pressure for barostat
Args:
pressure (float): Reference pressure for barostat.
"""
if self.barostat is not None:
self.barostat.set_pressure(pressure)
return self
[文档] def set_thermostat(self, thermostat: Thermostat, temperature: float = None):
r"""
Set thermostat
Args:
thermostat (Thermostat): Thermostat for temperature coupling.
temperature (float): Reference temperature for thermostat.
"""
if temperature is None:
temperature = self.ref_temp
thermostat = get_thermostat(thermostat, self.system, temperature)
if temperature is not None and thermostat is None:
raise ValueError('The `thermostat` cannot be None when setting the `temperature`')
if thermostat is None:
self.thermostat = None
else:
self.integrator.set_thermostat(thermostat)
self.thermostat = self.integrator.thermostat
return self
[文档] def set_barostat(self, barostat: Barostat, pressure: float = None):
r"""
Set barostat
Args:
barostat (Barostat): Barostat for pressure coupling.
pressure (float): Reference pressure for barostat.
"""
if pressure is None:
pressure = self.ref_press
barostat = get_barostat(barostat, self.system, pressure)
if pressure is not None and barostat is None:
raise ValueError('The `barostat` cannot be None when setting the `pressure`')
if barostat is None:
self.barostat = None
else:
if self.pbc_box is None:
raise ValueError('Barostat cannot be used for the system without periodic boundary condition.')
self.integrator.set_barostat(barostat)
self.barostat = self.integrator.barostat
return self
[文档] def set_constraint(self, constraint: Union[Constraint, List[Constraint]]):
r"""
Set constraint.
Args:
constraint (Union[`sponge.control.Constraint`, List[`sponge.control.Constraint`]]):
Constraint controller(s) for bond constraint.
"""
constraint = get_constraint(constraint, self.system)
if constraint is None:
self.constraint = None
else:
self.integrator.set_constraint(constraint, self.num_constraints)
self.constraint = self.integrator.constraint
self.set_degrees_of_freedom(self.integrator.degrees_of_freedom)
return self
def construct(self, energy: Tensor, force: Tensor, virial: Tensor = None):
r"""
Update the parameters of system
Args:
energy (Tensor): Total potential energy of the simulation system.
Tensor of shape :math:`(B, 1)`.
Here :math:`B` is the batch size.
Data type is float.
force (Tensor): Force on each atoms of the simulation system.
Tensor of shape :math:`(B, A, D)`.
Here :math:`A` is the number of atoms,
:math:`D` is the spatial dimension of the simulation system,
which is usually 3.
Data type is float.
virial (Tensor): Virial tensor of the simulation system.
Tensor of shape :math:`(B, D, D)`.
Data type is float.
Default: ``None``.
Returns:
bool, whether successfully finish the current optimization step and move to next step.
"""
force, virial = self.decay_and_scale_grad(force, virial)
coordinate = self.coordinate
velocity = self.velocity
kinetics = self.kinetics
pbc_box = self.pbc_box
step = self.identity(self.step)
coordinate, velocity, force, energy, kinetics, virial, pbc_box = \
self.integrator(coordinate, velocity, force, energy, kinetics, virial, pbc_box, step)
if self.controller is not None:
for i in range(self.num_controller):
coordinate, velocity, force, energy, kinetics, virial, pbc_box = \
self.controller[i](coordinate, velocity, force, energy, kinetics, virial, pbc_box, step)
temperature = self.get_temperature(kinetics)
pressure = self.get_pressure(kinetics, virial, pbc_box)
success = True
success = self.update_coordinate(coordinate, success)
success = self.update_velocity(velocity, success)
success = self.update_pbc_box(pbc_box, success)
success = self.update_kinetics(kinetics, success)
success = self.update_temperature(temperature, success)
success = self.update_virial(virial, success)
success = self.update_pressure(pressure, success)
return self.next_step(success)