# 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.
# ============================================================================
"""
Common functions
"""
from typing import Union, List, Tuple, Iterable
from datetime import time, timedelta, date
import numpy as np
from numpy import ndarray
import mindspore as ms
try:
# MindSpore 2.X
from mindspore import jit
except ImportError:
# MindSpore 1.X
from mindspore import ms_function as jit
import mindspore.numpy as msnp
from mindspore.numpy.utils import _to_tensor
from mindspore import ops, Tensor, Parameter
from mindspore.ops import functional as F
from mindspore.common.initializer import Initializer, _INITIALIZER_ALIAS
__all__ = [
'PI',
'keepdims_sum',
'keepdims_mean',
'keepdims_prod',
'reduce_any',
'reduce_all',
'reduce_prod',
'concat_first_dim',
'concat_last_dim',
'concat_penulti',
'stack_first_dim',
'stack_last_dim',
'stack_penulti',
'squeeze_first_dim',
'squeeze_last_dim',
'squeeze_penulti',
'identity',
'periodic_variable',
'periodic_difference',
'gather_vector',
'gather_value',
'pbc_box_reshape',
'pbc_image',
'coordinate_in_pbc',
'vector_in_pbc',
'calc_vector_nopbc',
'calc_vector_pbc',
'calc_vector',
'calc_distance_nopbc',
'calc_distance_pbc',
'calc_distance',
'calc_angle_by_vectors',
'calc_angle_nopbc',
'calc_angle_pbc',
'calc_angle',
'calc_torsion_by_vectors',
'calc_torsion_nopbc',
'calc_torsion_pbc',
'calc_torsion',
'coulomb_interaction',
'lennard_jones_potential',
'lennard_jones_potential2',
'get_integer',
'get_ndarray',
'get_tensor',
'get_ms_array',
'check_broadcast',
'any_none',
'all_none',
'any_not_none',
'all_not_none',
'get_arguments',
'get_initializer',
'bonds_in'
]
PI = 3.141592653589793238462643383279502884197169399375105820974944592307
r""":math:`\pi`"""
keepdims_sum_ = ops.ReduceSum(True)
keepdims_mean_ = ops.ReduceMean(True)
keepdims_prod_ = ops.ReduceProd(True)
reduce_any_ = ops.ReduceAny()
reduce_all_ = ops.ReduceAll()
reduce_prod_ = ops.ReduceProd()
concat_first_dim_ = ops.Concat(0)
concat_last_dim_ = ops.Concat(-1)
concat_penulti_ = ops.Concat(-2)
stack_first_dim_ = ops.Stack(0)
stack_last_dim_ = ops.Stack(-1)
stack_penulti_ = ops.Stack(-2)
squeeze_first_dim_ = ops.Squeeze(0)
squeeze_last_dim_ = ops.Squeeze(-1)
squeeze_penulti_ = ops.Squeeze(-2)
identity_ = ops.Identity()
def keepdims_sum(x: Tensor, axis: Union[int, Tuple[int], List[int]] = ()) -> Tensor:
"""
Reduces a dimension to 1 by summing the elements in the dimension of `x` along the axis,
and the dimensions of the output and input are the same.
Args:
- **x** (Tensor[Number]) - The input tensor. The dtype of the tensor to be reduced is number.
:math:`(N,*)` where :math:`*` means, any number of additional dimensions, its rank should be less than 8.
- **axis** (Union[int, tuple(int), list(int)]) - The dimensions to reduce. Default: (), reduce all dimensions.
Only constant value is allowed. Must be in the range [-rank(`x`), rank(`x`)).
Outputs:
Tensor, has the same dtype as the `x`.
Supported Platforms:
``Ascend`` ``GPU`` ``CPU``
"""
return keepdims_sum_(x, axis)
def keepdims_mean(x: Tensor, axis: Union[int, Tuple[int], List[int]] = ()) -> Tensor:
"""
Reduces a dimension to 1 by averaging the elements in the dimension of `x` along the axis,
and the dimensions of the output and input are the same.
Args:
- **x** (Tensor[Number]) - The input tensor. The dtype of the tensor to be reduced is number.
:math:`(N,*)` where :math:`*` means, any number of additional dimensions, its rank should be less than 8.
- **axis** (Union[int, tuple(int), list(int)]) - The dimensions to reduce. Default: (), reduce all dimensions.
Only constant value is allowed. Must be in the range [-rank(`x`), rank(`x`)).
Outputs:
Tensor, has the same dtype as the `x`.
Supported Platforms:
``Ascend`` ``GPU`` ``CPU``
"""
return keepdims_mean_(x, axis)
def keepdims_prod(x: Tensor, axis: Union[int, Tuple[int], List[int]] = ()) -> Tensor:
"""
Reduces a dimension to 1 by multiplying the elements in the dimension of `x` along the axis,
and the dimensions of the output and input are the same.
Args:
- **x** (Tensor[Number]) - The input tensor. The dtype of the tensor to be reduced is number.
:math:`(N,*)` where :math:`*` means, any number of additional dimensions, its rank should be less than 8.
- **axis** (Union[int, tuple(int), list(int)]) - The dimensions to reduce. Default: (), reduce all dimensions.
Only constant value is allowed. Must be in the range [-rank(`x`), rank(`x`)).
Outputs:
Tensor, has the same dtype as the `x`.
Supported Platforms:
``Ascend`` ``GPU`` ``CPU``
"""
return keepdims_prod_(x, axis)
def reduce_any(x: Tensor, axis: Union[int, Tuple[int], List[int]] = ()) -> Tensor:
r"""
Reduces a dimension of a tensor by the "logical OR" of all elements in the dimension, by default. And also can
reduce a dimension of `x` along the axis. See `mindspore.ops.ReduceAny` for detailed information.
Args:
- **x** (Tensor[bool]) - The input tensor. The dtype of the tensor to be reduced is bool.
:math:`(N,*)` where :math:`*` means, any number of additional dimensions, its rank should be less than 8.
- **axis** (Union[int, tuple(int), list(int)]) - The dimensions to reduce. Default: (), reduce all dimensions.
Only constant value is allowed. Must be in the range [-rank(x), rank(x)).
Outputs:
Tensor, the dtype is bool.
Supported Platforms:
``Ascend`` ``GPU`` ``CPU``
"""
return reduce_any_(x, axis)
def reduce_all(x: Tensor, axis: Union[int, Tuple[int], List[int]] = ()) -> Tensor:
r"""
Reduces a dimension of a tensor by the "logicalAND" of all elements in the dimension, by default. And also can
reduce a dimension of `x` along the axis. See `mindspore.ops.ReduceAll` for detailed information.
Args:
- **x** (Tensor[bool]) - The input tensor. The dtype of the tensor to be reduced is bool.
:math:`(N,*)` where :math:`*` means, any number of additional dimensions, its rank should be less than 8.
- **axis** (Union[int, tuple(int), list(int)]) - The dimensions to reduce. Default: (), reduce all dimensions.
Only constant value is allowed. Must be in the range [-rank(x), rank(x)).
Outputs:
Tensor, the dtype is bool.
Supported Platforms:
``Ascend`` ``GPU`` ``CPU``
"""
return reduce_all_(x, axis)
def reduce_prod(x: Tensor, axis: Union[int, Tuple[int], List[int]] = ()) -> Tensor:
r"""
Reduces a dimension of a tensor by multiplying all elements in the dimension, by default. And also can
reduce a dimension of `x` along the axis. See `mindspore.ops.ReduceProd` for detailed information.
Args:
- **x** (Tensor[Number]) - The input tensor. The dtype of the tensor to be reduced is number.
:math:`(N,*)` where :math:`*` means, any number of additional dimensions, its rank should be less than 8.
- **axis** (Union[int, tuple(int), list(int)]) - The dimensions to reduce. Default: (), reduce all dimensions.
Only constant value is allowed. Must be in the range [-r, r).
Outputs:
Tensor, has the same dtype as the `x`.
Supported Platforms:
``Ascend`` ``GPU`` ``CPU``
"""
return reduce_prod_(x, axis)
def concat_first_dim(input_x: Tensor) -> Tensor:
r"""
Connect tensor in the first axis (axis=0).
Connect input tensors along with the first axis.
Args:
input_x (Union[tuple, list]): A tuple or a list of input tensors.
Returns:
Tensor. A concatenated Tensor with the same type as `input_x`.
Supported Platforms:
``Ascend`` ``GPU`` ``CPU``
"""
return concat_first_dim_(input_x)
def concat_last_dim(input_x: Tensor) -> Tensor:
r"""
Connect tensor in the last axis (axis=-1).
Connect input tensors along with the last axis.
Args:
input_x (Union[tuple, list]): A tuple or a list of input tensors.
Returns:
Tensor. A concatenated Tensor with the same type as `input_x`.
Supported Platforms:
``Ascend`` ``GPU`` ``CPU``
"""
return concat_last_dim_(input_x)
def concat_penulti(input_x: Tensor) -> Tensor:
r"""
Connect tensor in the penultimate axis (axis=-2).
Connect input tensors along with the penultimate axis.
Args:
input_x (Union[tuple, list]): A tuple or a list of input tensors.
Returns:
Tensor. A concatenated Tensor with the same type as `input_x`.
Supported Platforms:
``Ascend`` ``GPU`` ``CPU``
"""
return concat_penulti_(input_x)
def stack_first_dim(input_x: Tensor) -> Tensor:
r"""
Stacks a list of tensors in the first axis (axis=0).
Args:
input_x (Union[tuple, list]): A Tuple or list of Tensor objects with the same shape and type.
Returns:
Tensor. A stacked Tensor with the same type as `input_x`.
Supported Platforms:
``Ascend`` ``GPU`` ``CPU``
"""
return stack_first_dim_(input_x)
def stack_last_dim(input_x: Tensor) -> Tensor:
r"""
Stacks a list of tensors in the last axis (axis=-1).
Args:
input_x (Union[tuple, list]): A Tuple or list of Tensor objects with the same shape and type.
Returns:
Tensor. A stacked Tensor with the same type as `input_x`.
Supported Platforms:
``Ascend`` ``GPU`` ``CPU``
"""
return stack_last_dim_(input_x)
def stack_penulti(input_x: Tensor) -> Tensor:
r"""
Stacks a list of tensors in the penultimate axis (axis=-2).
Args:
input_x (Union[tuple, list]): A Tuple or list of Tensor objects with the same shape and type.
Returns:
Tensor. A stacked Tensor with the same type as `input_x`.
Supported Platforms:
``Ascend`` ``GPU`` ``CPU``
"""
return stack_penulti_(input_x)
def squeeze_first_dim(input_x: Tensor) -> Tensor:
r"""
Return the Tensor after deleting the dimension of size 1 from the first axis (axis=0).
Args:
input_x (Tensor): The shape of tensor is :math:`(x_1, x_2, ..., x_R)`.
Returns:
Tensor, the shape of tensor is :math:`(x_2, ..., x_R)`.
Supported Platforms:
``Ascend`` ``GPU`` ``CPU``
"""
return squeeze_first_dim_(input_x)
def squeeze_last_dim(input_x: Tensor) -> Tensor:
r"""
Return the Tensor after deleting the dimension of size 1 from the last axis (axis=-1).
Args:
input_x (Tensor): The shape of tensor is :math:`(x_1, x_2, ..., x_R)`.
Returns:
Tensor, the shape of tensor is :math:`(x_1, x_2, ..., x_{R-1})`.
Supported Platforms:
``Ascend`` ``GPU`` ``CPU``
"""
return squeeze_last_dim_(input_x)
def squeeze_penulti(input_x: Tensor) -> Tensor:
r"""
Return the Tensor after deleting the dimension of size 1 from the penultimate axis (axis=-2).
Args:
input_x (Tensor): The shape of tensor is :math:`(x_1, x_2, ..., x_{R-1}, x_R)`.
Returns:
Tensor, the shape of tensor is :math:`(x_1, x_2, ..., x_R)`.
Supported Platforms:
``Ascend`` ``GPU`` ``CPU``
"""
return squeeze_penulti_(input_x)
def identity(x: Tensor) -> Tensor:
r"""
Returns a Tensor with the same shape and contents as input.
Args:
- **x** (Tensor) - The shape of tensor is :math:`(x_1, x_2, ..., x_R)`. The data type is Number.
Returns:
Tensor, the shape of tensor and the data type are the same as `input_x`, :math:`(x_1, x_2, ..., x_R)`.
Supported Platforms:
``Ascend`` ``GPU`` ``CPU``
"""
return identity_(x)
@jit
def periodic_variable(variable: Tensor,
upper: Tensor,
lower: Tensor = 0,
mask: Tensor = None,
) -> Tensor:
r"""get the value in the periodic range.
Args:
variable (Tensor): Tensor of shape `(...)`. Data type is float.
Periodic variable
upper (Tensor): Tensor of shape `(...)`. Data type is float.
Upper boundary of perodicity.
lower (Tensor): Tensor of shape `(...)`. Data type is float.
Lower boundary of perodicity. Default: 0
mask (Tensor): Tensor of shape `(...)`. Data type is bool_.
Mask for the periodic variable.
Returns:
period_value (Tensor): Tensor of shape `(...)`. Data type is float.
Variable with value in the periodic range.
Supported Platforms:
``Ascend`` ``GPU``
"""
period = upper - lower
period_value = variable - period * F.floor((variable - lower) / period)
if mask is None:
return period_value
if mask.shape != variable.shape:
mask = msnp.broadcast_to(mask, variable.shape)
return F.select(mask, period_value, variable)
@jit
def periodic_difference(difference: Tensor,
period: Tensor,
mask: Tensor = None,
offset: float = -0.5,
) -> Tensor:
r"""get value of difference between periodic variables.
Args:
variable (Tensor): Tensor of shape `(...)`. Data type is float.
Periodic variable
period (Tensor): Tensor of shape `(...)`. Data type is float.
Upper boundary of perodicity.
mask (Tensor): Tensor of shape `(...)`. Data type is bool_.
Mask for the periodic variable.
offset (float): Offset ratio :math:`c` with relative to the period :math:`\theta`.
Default: -0.5
Returns:
period_diff (Tensor): Tensor of shape `(...)`. Data type is float.
Variable with value in the periodic range.
Supported Platforms:
``Ascend`` ``GPU``
"""
period_diff = difference - period * F.floor(difference / period - offset)
if mask is None:
return period_diff
if mask.shape != difference.shape:
mask = msnp.broadcast_to(mask, difference.shape)
return F.select(mask, period_diff, difference)
[文档]@jit
def gather_vector(tensor: Tensor, index: Tensor) -> Tensor:
r"""Gather vector from the penultimate axis (`axis=-2`) of the tensor according to index.
Args:
tensor (Tensor): Tensor of shape :math:`(B, X, D)`, where :math:`B` is batch size, :math:`X` is an
arbitrary value., :math:`D` is spatial dimension of the simulation system, usually is 3.
index (Tensor): Tensor of shape :math:`(B, ...,)`. Data type is int.
Returns:
vector (Tensor), a tensor of shape :math:`(B, ..., D)`
Supported Platforms:
``Ascend`` ``GPU``
"""
if index.shape[0] == 1:
return F.gather(tensor, index[0], -2)
if tensor.shape[0] == 1:
return F.gather(tensor[0], index, -2)
# (B, N, M)
shape0 = index.shape
# (B, N * M, 1) <- (B, N, M)
index = F.reshape(index, (shape0[0], -1, 1))
# (B, N * M, D) <- (B, N, D)
vectors = msnp.take_along_axis(tensor, index, axis=-2)
# (B, N, M, D) <- (B, N, M) + (D,)
output_shape = shape0 + tensor.shape[-1:]
# (B, N, M, D)
return F.reshape(vectors, output_shape)
[文档]@jit
def gather_value(tensor: Tensor, index: Tensor) -> Tensor:
r"""Gather value from the last axis (`axis=-1`) of the tensor according to index.
Args:
tensor (Tensor): Tensor of shape `(B, X)`, where :math:`B` is batch_size,
and :math:`X` is an arbitrary value.
index (Tensor): Tensor of shape `(B, ...,)`. Data type is int.
Returns:
value (Tensor), a tensor of shape `(B, ...,)` .
Supported Platforms:
``Ascend`` ``GPU``
"""
if index.shape[0] == 1:
return F.gather(tensor, index[0], -1)
if tensor.shape[0] == 1:
return F.gather(tensor[0], index, -1)
# (B, N, M)
origin_shape = index.shape
# (B, N * M) <- (B, N, M)
index = F.reshape(index, (origin_shape[0], -1))
# (B, N * M)
values = F.gather_d(tensor, -1, index)
# (B, N, M)
return F.reshape(values, origin_shape)
[文档]@jit
def pbc_box_reshape(pbc_box: Tensor, ndim: int) -> Tensor:
r"""Reshape the pbc_box as the same ndim.
Args:
pbc_box (Tensor): Tensor of shape :math:`(B, D)`. Data type is float.
B is batchsize, i.e. number of walkers in simulation.
D is spatial dimension of the simulation system. Usually is 3.
ndim (int): The rank (number of dimension) of the pbc_box
Returns:
pbc_box (Tensor), a tensor of shape :math:`(B, 1, .., 1, D)`. Data type is float.
Supported Platforms:
``Ascend`` ``GPU``
"""
if ndim <= 2:
return pbc_box
shape = pbc_box.shape[:1] + (1,) * (ndim - 2) + pbc_box.shape[-1:]
return F.reshape(pbc_box, shape)
[文档]@jit
def pbc_image(position: Tensor, pbc_box: Tensor, offset: float = 0) -> Tensor:
r"""calculate the periodic image of the PBC box
Args:
position (Tensor): Tensor of shape :math:`(B, ..., D)`. Data type is float.
B is batchsize, i.e. number of walkers in simulation
D is spatial dimension of the simulation system. Usually is 3.
pbc_box (Tensor): Tensor of shape :math:`(B, D)`. Data type is float.
offset (float): Offset ratio :math:`c` relative to box size :math:`\vec{L}`.
Default: ``0``
Returns:
image (Tensor), a tensor of shape :math:`(B, ..., D)`. Data type is int32.
Supported Platforms:
``Ascend`` ``GPU``
"""
pbc_box = pbc_box_reshape(F.stop_gradient(pbc_box), position.ndim)
image = -F.floor(position / pbc_box - offset)
return F.cast(image, ms.int32)
@jit
def coordinate_in_pbc(position: Tensor, pbc_box: Tensor, offset: float = 0) -> Tensor:
r"""get coordinate in main PBC box
Args:
position (Tensor): Tensor of shape `(B, ..., D)`. Data type is float.
Position coordinate :math:`R`
pbc_box (Tensor): Tensor of shape `(B, D)`. Data type is float.
Size of PBC box :math:`\vec{L}`
offset (float): Offset ratio :math:`c` relative to box size :math:`\vec{L}`.
Default: 0
Returns:
coordinate (Tensor): Tensor of shape `(B, ..., D)`. Data type is float.
Supported Platforms:
``Ascend`` ``GPU``
Note:
B: Batchsize, i.e. number of walkers in simulation
D: Spatial dimension of the simulation system. Usually is 3.
"""
pbc_box = pbc_box_reshape(F.stop_gradient(pbc_box), position.ndim)
return position - pbc_box * F.floor(position / pbc_box - offset)
[文档]@jit
def vector_in_pbc(vector: Tensor, pbc_box: Tensor, offset: float = -0.5) -> Tensor:
r"""
Make the value of vector :math:`\vec{v}` at a single PBC box :math:`\vec{L}`.
Note:
B: Batchsize, i.e. number of walkers in simulation
D: Spatial dimension of the simulation system. Usually is 3.
Args:
vector (Tensor): Tensor of shape `(B, ..., D)`. Data type is float.
Vector :math:`\vec{v}`.
pbc_box (Tensor): Tensor of shape `(B, D)`. Data type is float.
Size of PBC box :math:`\vec{L}`.
offset (float): Offset ratio :math:`c` of the vector relative to box size :math:`\vec{L}`.
The value of vector will be between :math:`c \vec{L}` and
:math:`(c+1) \vec{L}`. Default: ``-0.5``.
Returns:
pbc_vector (Tensor), a tensor of shape `(B, ..., D)`. Data type is float.
Supported Platforms:
``Ascend`` ``GPU``
"""
pbc_box = pbc_box_reshape(pbc_box, vector.ndim)
box_nograd = F.stop_gradient(pbc_box)
inv_box = msnp.reciprocal(box_nograd)
vector -= box_nograd * F.floor(vector * inv_box - offset)
return vector * inv_box * pbc_box
[文档]@jit
def calc_vector_nopbc(initial: Tensor, terminal: Tensor) -> Tensor:
r"""Compute vector from initial point to terminal point without perodic bundary condition.
Args:
initial (Tensor): Tensor of shape :math:`(..., D)`, where :math:`D` is the spatial
dimension of the simulation system (usually 3). Data type is float.
Position coordinate of initial point
terminal (Tensor): Tensor of shape :math:`(..., D)`. Data type is float.
Position coordinate of terminal point
Returns:
vector (Tensor), a tensor of shape :math:`(..., D)`. Data type is float.
Supported Platforms:
``Ascend`` ``GPU``
"""
return terminal - initial
[文档]@jit
def calc_vector_pbc(initial: Tensor, terminal: Tensor, pbc_box: Tensor) -> Tensor:
r"""Compute vector from initial point to terminal point at perodic bundary condition.
Args:
initial (Tensor): Tensor of shape :math:`(..., D)`, where :math:`D` is the spatial
dimension of the simulation system (usually 3). Data type is float.
Position coordinate of initial point
terminal (Tensor): Tensor of shape :math:`(..., D)`. Data type is float.
Position coordinate of terminal point
pbc_box (Tensor): Tensor of shape :math:`(D)` or :math:`(B, D)`, where :math:`B` is
the batchsize (i.e., number of walkers in simulation). Data type is float.
Size of PBC box.
Returns:
vector (Tensor), a tensor of shape :math:`(..., D)`. Data type is float.
Supported Platforms:
``Ascend`` ``GPU``
"""
return vector_in_pbc(terminal-initial, pbc_box)
[文档]@jit
def calc_vector(initial: Tensor, terminal: Tensor, pbc_box: Tensor = None) -> Tensor:
r"""Compute vector from initial point to terminal point.
Args:
initial (Tensor): Tensor of shape :math:`(..., D)`, where :math:`D` is the spatial
dimension of the simulation system (usually 3). Data type is float.
Position coordinate of initial point
terminal (Tensor): Tensor of shape :math:`(..., D)`. Data type is float.
Position coordinate of terminal point.
pbc_box (Tensor): Tensor of shape :math:`(D)` or :math:`(B, D)`, where :math:`B` is
the batchsize (i.e., number of walkers in simulation). Data type is float.
Default: ``None``
Returns:
vector (Tensor, a tensor of shape `(..., D)`). Data type is float.
Supported Platforms:
``Ascend`` ``GPU``
"""
vector = terminal - initial
if pbc_box is None:
return vector
return vector_in_pbc(vector, pbc_box)
[文档]@jit
def calc_distance_nopbc(position_a: Tensor,
position_b: Tensor,
keepdims: bool = False,
) -> Tensor:
r"""Compute distance between position A and B without perodic bundary condition.
Args:
position_a (Tensor): Tensor of shape :math:`(..., D)`. Data type is float.
D is spatial dimension of the simulation system. Usually is 3.
Position coordinate of point :math:`A`.
position_b (Tensor): Tensor of shape :math:`(..., D)`. Data type is float.
Position coordinate of point :math:`B`.
keepdims (bool): If this is set to ``True``, the last axis will be left
in the result as dimensions with size one.
Default: ``False``.
Returns:
distance (Tensor), a tensor of shape :math:`(...)` or :math:`(..., 1)`. Data type is float.
Supported Platforms:
``Ascend`` ``GPU``
"""
vec = calc_vector_nopbc(position_a, position_b)
return msnp.norm(vec, axis=-1, keepdims=keepdims)
[文档]@jit
def calc_distance_pbc(position_a: Tensor,
position_b: Tensor,
pbc_box: Tensor = None,
keepdims: bool = False
) -> Tensor:
r"""Compute distance between position :math:`A` and :math:`B` at perodic bundary condition.
Args:
position_a (Tensor): Tensor of shape :math:`(..., D)`. Data type is float.
D means spatial dimension of the simulation system. Usually is 3.
Position coordinate of point :math:`A`.
position_b (Tensor): Tensor of shape :math:`(..., D)`. Data type is float.
Position coordinate of point :math:`B`.
pbc_box (Tensor): Tensor of shape :math:`(D)` or :math:`(B, D)`. Data type is float.
B means batchsize, i.e. number of walkers in simulation
Size of PBC box :math:`\vec{L}`
keepdims (bool): If this is set to ``True``, the last axis will be left
in the result as dimensions with size one.
Default: ``False``.
Returns:
distance (Tensor), a tensor of shape :math:`(...)` or :math:`(..., 1)`. Data type is float.
Supported Platforms:
``Ascend`` ``GPU``
"""
vec = calc_vector_pbc(position_a, position_b, pbc_box)
return msnp.norm(vec, axis=-1, keepdims=keepdims)
[文档]@jit
def calc_distance(position_a: Tensor,
position_b: Tensor,
pbc_box: Tensor = None,
keepdims: bool = False,
) -> Tensor:
r"""Compute distance between position :math:`A` and :math:`B`.
Args:
position_a (Tensor): Tensor of shape :math:`(..., D)`. Data type is float.
Position coordinate of point :math:`A`.
position_b (Tensor): Tensor of shape :math:`(..., D)`. Data type is float.
Position coordinate of point :math:`B`.
pbc_box (Tensor): Tensor of shape :math:`(D)` or :math:`(B, D)`. Data type is float.
Size of PBC box :math:`\vec{L}`
keepdims (bool): If this is set to ``True`` , the last axis will be left
in the result as dimensions with size one.
Default: ``False`` .
Returns:
distance (Tensor), a tensor of shape :math:`(...)` or :math:`(..., 1)` . Data type is float.
Supported Platforms:
``Ascend`` ``GPU``
"""
vec = calc_vector_nopbc(position_a, position_b)
if pbc_box is not None:
vec = vector_in_pbc(vec, pbc_box)
return msnp.norm(vec, axis=-1, keepdims=keepdims)
[文档]@jit
def calc_angle_by_vectors(vector1: Tensor,
vector2: Tensor,
keepdims: bool = False
) -> Tensor:
r"""Compute angle between two vectors.
For vector :math:`\vec {v_1} = (x_1, x_2, x_3, ..., x_n)` and
:math:`\vec {v_2} = (y_1, y_2, y_3, ..., y_n)` , the formula is
.. math::
\theta = \arccos {\frac{|x_1y_1 + x_2y_2 + \cdots + x_ny_n|}{\sqrt{x_1^2 + x_2^2 +
\cdots + x_n^2}\sqrt{y_1^2 + y_2^2 + \cdots + y_n^2}}}
Args:
vector1 (Tensor): Tensor of shape :math:`(..., D)`. Data type is float.
D means spatial dimension of the simulation system. Usually is 3.
Vector of :math:`\vec{v_1}`.
vector2 (Tensor): Tensor of shape :math:`(..., D)`. Data type is float.
Vector of :math:`\vec{v_2}`.
keepdims (bool): If this is set to True, the last axis will be left
in the result as dimensions with size one.
Default: ``False``.
Returns:
angle (Tensor), a tensor of shape :math:`(...)` or :math:`(..., 1)`. Data type is float.
Supported Platforms:
``Ascend`` ``GPU``
"""
# (...) or (..., 1) <- (..., D)
dis1 = msnp.norm(vector1, axis=-1, keepdims=keepdims)
dis2 = msnp.norm(vector2, axis=-1, keepdims=keepdims)
dot12 = msnp.sum(vector1*vector2, axis=-1, keepdims=keepdims)
# (...) or (..., 1)
cos_theta = dot12 / dis1 / dis2
return F.acos(cos_theta)
[文档]@jit
def calc_angle_nopbc(position_a: Tensor,
position_b: Tensor,
position_c: Tensor,
keepdims: bool = False,
) -> Tensor:
r"""Compute angle :math:`\angle{ABC}` formed by the position coordinates of three positions
:math:`A`, :math:`B` and :math:`C` without periodic boundary condition.
Args:
position_a (Tensor): Tensor of shape `(..., D)`. Data type is float.
D means spatial dimension of the simulation system. Usually is 3.
Position coordinate of point :math:`A`.
position_b (Tensor): Tensor of shape `(..., D)`. Data type is float.
Position coordinate of point :math:`B`.
position_c (Tensor): Tensor of shape `(..., D)`. Data type is float.
Position coordinate of point :math:`C`.
keepdims (bool): If this is set to True, the last axis will be left
in the result as dimensions with size one.
Default: ``False``.
Returns:
angle (Tensor), a tensor of shape `(...)` or `(..., 1)`. Data type is float.
Value of angle :math:`\angle{ABC}`.
Supported Platforms:
``Ascend`` ``GPU``
"""
# (...,D)
vec_ba = calc_vector_nopbc(position_b, position_a)
vec_bc = calc_vector_nopbc(position_b, position_c)
return calc_angle_by_vectors(vec_ba, vec_bc, keepdims=keepdims)
[文档]@jit
def calc_angle_pbc(position_a: Tensor,
position_b: Tensor,
position_c: Tensor,
pbc_box: Tensor,
keepdims: bool = False,
) -> Tensor:
r"""Compute angle :math:`\angle{ABC}` formed by the position coordinates of three positions
:math:`A`, :math:`B` and :math:`C` at periodic boundary condition.
Args:
position_a (Tensor): Tensor of shape :math:`(..., D)` . Data type is float.
D means spatial dimension of the simulation system. Usually is 3.
Position coordinate of point :math:`A`.
position_b (Tensor): Tensor of shape :math:`(..., D)` . Data type is float.
Position coordinate of point :math:`B`.
position_c (Tensor): Tensor of shape :math:`(..., D)` . Data type is float.
Position coordinate of point :math:`C`.
pbc_box (Tensor): Tensor of shape :math:`(D)` or :math:`(B, D)` . Data type is float.
B means batchsize, i.e. number of walkers in simulation
Size of PBC box :math:`\vec{L}`
keepdims (bool): If this is set to True, the last axis will be left
in the result as dimensions with size one.
Default: ``False`` .
Returns:
angle (Tensor), a tensor of shape :math:`(...)` or :math:`(..., 1)` . Data type is float.
Supported Platforms:
``Ascend`` ``GPU``
"""
# (B, ..., D)
vec_ba = calc_vector_pbc(position_b, position_a, pbc_box)
vec_bc = calc_vector_pbc(position_b, position_c, pbc_box)
return calc_angle_by_vectors(vec_ba, vec_bc, keepdims=keepdims)
[文档]@jit
def calc_angle(position_a: Tensor,
position_b: Tensor,
position_c: Tensor,
pbc_box: Tensor = None,
keepdims: bool = False,
) -> Tensor:
r"""
Compute angle formed by three positions :math:`A`, :math:`B` and :math:`C`
with or without periodic boundary condition.
Args:
position_a (Tensor): Tensor of shape :math:`(..., D)` . Data type is float.
D means spatial dimension of the simulation system. Usually is 3.
Position coordinate of point :math:`A`.
position_b (Tensor): Tensor of shape :math:`(..., D)` . Data type is float.
Position coordinate of point :math:`B`.
position_c (Tensor): Tensor of shape :math:`(..., D)` . Data type is float.
Position coordinate of point :math:`C`.
pbc_box (Tensor): Tensor of shape :math:`(D)` or :math:`(B, D)` . Data type is float.
B means batchsize, i.e. number of walkers in simulation
Size of PBC box :math:`\vec{L}`. Default: ``None``.
keepdims (bool): If this is set to True, the last axis will be left
in the result as dimensions with size one.
Default: ``False``.
Returns:
angle (Tensor), a tensor of shape :math:`(...)` or :math:`(..., 1)`. Data type is float.
Supported Platforms:
``Ascend`` ``GPU``
"""
if pbc_box is None:
return calc_angle_nopbc(position_a, position_b, position_c, keepdims=keepdims)
return calc_angle_pbc(position_a, position_b, position_c, pbc_box=pbc_box, keepdims=keepdims)
[文档]@jit
def calc_torsion_by_vectors(vector1: Tensor,
vector2: Tensor,
axis_vector: Tensor = None,
keepdims: bool = False,
) -> Tensor:
r"""Compute torsion angle formed by two direction vectors :math:`\vec{v_1}` and :math:`\vec{v_2}`
and an axis vector :math:`\vec{v_{axis}}`.
Args:
vector1 (Tensor): Tensor of shape :math:`(..., D)`. Data type is float.
D is spatial dimension of the simulation system. Usually is 3.
Direction vector :math:`\vec{v_1}`
vector2 (Tensor): Tensor of shape :math:`(..., D)`. Data type is float.
Direction vector :math:`\vec{v_2}`
axis_vector (Tensor): Tensor of shape :math:`(..., D)`. Data type is float.
Axis vector :math:`\vec{v_{axis}}`.
Default: ``None``.
keepdims (bool): If this is set to True, the last axis will be left
in the result as dimensions with size one.
Default: ``False``.
Returns:
torsion (Tensor), a tensor of shape :math:`(...)` or :math:`(..., 1)`. Data type is float.
Supported Platforms:
``Ascend`` ``GPU``
"""
if axis_vector is None:
return calc_angle_by_vectors(vector1, vector2, keepdims=keepdims)
# (..., D)
vec_a = msnp.cross(vector1, axis_vector)
vec_b = msnp.cross(vector2, axis_vector)
cross_ab = msnp.cross(vec_a, vec_b)
# (..., 1) <- (..., D)
axis_norm = msnp.norm(axis_vector, axis=-1, keepdims=True)
# (..., D) = (..., D) / (..., 1)
axis_vector *= msnp.reciprocal(axis_norm)
# (...) or (..., 1)
sin_phi = msnp.sum(axis_vector*cross_ab, axis=-1, keepdims=keepdims)
cos_phi = msnp.sum(vec_a*vec_b, axis=-1, keepdims=keepdims)
return F.atan2(sin_phi, cos_phi)
[文档]@jit
def calc_torsion_nopbc(position_a: Tensor,
position_b: Tensor,
position_c: Tensor,
position_d: Tensor,
keepdims: bool = False,
) -> Tensor:
r"""
Compute torsion angle `A-B-C-D` formed by four positions :math:`A`, :math:`B`,
:math:`C` and :math:`D` without periodic boundary condition.
Args:
position_a (Tensor): Tensor of shape :math:`(..., D)`. Data type is float.
D is spatial dimension of the simulation system. Usually is 3.
Position coordinate of point :math:`A`.
position_b (Tensor): Tensor of shape :math:`(..., D)`. Data type is float.
Position coordinate of point :math:`B`.
position_c (Tensor): Tensor of shape :math:`(..., D)`. Data type is float.
Position coordinate of point :math:`C`.
position_d (Tensor): Tensor of shape :math:`(..., D)`. Data type is float.
Position coordinate of point :math:`D`.
keepdims (bool): If this is set to ``True``, the last axis will be left
in the result as dimensions with size one.
Default: ``False``.
Returns:
torsion (Tensor), a tensor of shape :math:`(...)` or :math:`(..., 1)`. Data type is float.
Supported Platforms:
``Ascend`` ``GPU``
"""
vec_ba = calc_vector_nopbc(position_b, position_a)
vec_cd = calc_vector_nopbc(position_c, position_d)
vec_bc = calc_vector_nopbc(position_b, position_c)
return calc_torsion_by_vectors(vec_ba, vec_cd, axis_vector=vec_bc, keepdims=keepdims)
[文档]@jit
def calc_torsion_pbc(position_a: Tensor,
position_b: Tensor,
position_c: Tensor,
position_d: Tensor,
pbc_box: Tensor,
keepdims: bool = False,
) -> Tensor:
r"""
Compute torsion angle `A-B-C-D` formed by four positions :math:`A`, :math:`B`,
:math:`C` and :math:`D` at periodic boundary condition.
Args:
position_a (Tensor): Tensor of shape :math:`(..., D)`. Data type is float.
D is spatial dimension of the simulation system. Usually is 3.
Position coordinate of point :math:`A`.
position_b (Tensor): Tensor of shape :math:`(..., D)`. Data type is float.
Position coordinate of point :math:`B`.
position_c (Tensor): Tensor of shape :math:`(..., D)`. Data type is float.
Position coordinate of point :math:`C`.
position_d (Tensor): Tensor of shape :math:`(..., D)`. Data type is float.
Position coordinate of point :math:`D`.
pbc_box (Tensor): Tensor of shape :math:`(D)` or :math:`(B, D)`. Data type is float.
B is batchsize, i.e. number of walkers in simulation
Size of PBC box :math:`\vec{L}`.
keepdims (bool): If this is set to ``True``, the last axis will be left
in the result as dimensions with size one.
Default: ``False``.
Returns:
torsion (Tensor), a tensor of shape :math:`(...)` or :math:`(..., 1)`. Data type is float.
Supported Platforms:
``Ascend`` ``GPU``
"""
vec_ba = calc_vector_pbc(position_b, position_a, pbc_box)
vec_cd = calc_vector_pbc(position_c, position_d, pbc_box)
vec_bc = calc_vector_pbc(position_b, position_c, pbc_box)
return calc_torsion_by_vectors(vec_ba, vec_cd, axis_vector=vec_bc, keepdims=keepdims)
[文档]@jit
def calc_torsion(position_a: Tensor,
position_b: Tensor,
position_c: Tensor,
position_d: Tensor,
pbc_box: Tensor = None,
keepdims: bool = False,
) -> Tensor:
r"""Compute torsion angle :math:`A-B-C-D` formed by four positions :math:`A`, :math:`B`, :math:`C` and :math:`D`
with or without periodic boundary condition.
Args:
position_a (Tensor): Tensor of shape :math:`(..., D)`. Data type is float.
D is spatial dimension of the simulation system. Usually is 3.
Position coordinate of point :math:`A`.
position_b (Tensor): Tensor of shape :math:`(..., D)`. Data type is float.
Position coordinate of point :math:`B`.
position_c (Tensor): Tensor of shape :math:`(..., D)`. Data type is float.
Position coordinate of point :math:`C`.
position_d (Tensor): Tensor of shape :math:`(..., D)`. Data type is float.
Position coordinate of point :math:`D`.
pbc_box (Tensor): Tensor of shape :math:`(D)` or :math:`(B, D)`. Data type is float.
B is batchsize, i.e. number of walkers in simulation.
Size of PBC box :math:`\vec{L}`. Default: ``None``.
keepdims (bool): If this is set to ``True`` , the last axis will be left
in the result as dimensions with size one.
Default: ``False`` .
Returns:
torsion (Tensor), a tensor of shape :math:`(...)` or :math:`(..., 1)`. Data type is float.
Supported Platforms:
``Ascend`` ``GPU``
"""
if pbc_box is None:
return calc_torsion_nopbc(
position_a, position_b, position_c, position_d, keepdims=keepdims)
return calc_torsion_pbc(
position_a, position_b, position_c, position_d, pbc_box=pbc_box, keepdims=keepdims)
@jit
def coulomb_interaction(q_i: Tensor,
q_j: Tensor,
r_ij: Tensor,
mask: Tensor = None,
coulomb_const: float = 1,
):
r"""Calculate Coulomb interaction.
Math:
.. math::
E_{coulomb}(r_{ij}) = k \frac{q_i q_j}{r_{ij}}
Args:
q_i (Tensor): Tensor of shape `(...)`. Data type is float.
Charge of the :math:`i`-th atom :math:`q_i`.
q_j (Tensor): Tensor of shape `(...)`. Data type is float.
Charge of the :math:`j`-th atom :math:`q_j`.
r_ij (Tensor): Tensor of shape `(...)`. Data type is float.
Distance :math:`r_{ij}` between atoms :math:`i` and :math:`i`.
mask (Tensor): Tensor of shape `(...)`. Data type is bool.
Mask for distance :math:`r_{ij}`. Default: ``None``.
coulomb_const (float): Coulomb constant :math:`k`. Default: 1
Returns:
E_coulomb (Tensor): Tensor of shape `(...)`. Data type is float.
Supported Platforms:
``Ascend`` ``GPU``
"""
energy = coulomb_const * q_i * q_j * msnp.reciprocal(r_ij)
if mask is None:
return energy
return energy * mask
@jit
def lennard_jones_potential(epsilon: Tensor, sigma: Tensor, r_ij: Tensor, mask: Tensor = None) -> Tensor:
r"""Calculate Lennard-Jones (LJ) potential with :math:`\epsilon` and :math:`\sigma`.
Math:
.. math::
E_{lj}(r_{ij}) = 4 \epsilon \left [\left ( \frac{\sigma}{r_{ij}} \right ) ^{12} -
\left ( \frac{\sigma}{r_{ij}} \right ) ^{6} \right]
Args:
epsilon (Tensor): Tensor of shape `(...)`. Data type is float.
Well depth :math:`\epsilon`.
sigma (Tensor): Tensor of shape `(...)`. Data type is float.
Characteristic distance :math:`\sigma`.
r_ij (Tensor): Tensor of shape `(...)`. Data type is float.
Distance :math:`r_{ij}` between atoms :math:`i` and :math:`i`.
mask (Tensor): Tensor of shape `(...)`. Data type is bool.
Mask for distances :math:`r_{ij}`. Default: ``None``.
Returns:
E_coulomb (Tensor): Tensor of shape (...). Data type is float.
Supported Platforms:
``Ascend`` ``GPU``
"""
# (\sigma / r_{ij}) ^ 6
r0_6 = F.pows(sigma * msnp.reciprocal(r_ij), 6)
# 4 * \epsilon * (\sigma / r_{ij}) ^ 6
ene_bcoeff = 4 * epsilon * r0_6
# 4 * \epsilon * (\sigma / r_{ij}) ^ 12
ene_acoeff = ene_bcoeff * r0_6
energy = ene_acoeff - ene_bcoeff
if mask is None:
return energy
return energy * mask
@jit
def lennard_jones_potential2(epsilon: Tensor, r_0: Tensor, r_ij: Tensor, mask: Tensor = None) -> Tensor:
r"""Calculate Lennard-Jones (LJ) potential with :math:`\epsilon` and :math:`r_0`.
Math:
.. math::
E_{lj}(r_{ij}) = 4 \epsilon \left [\frac{1}{4} \left ( \frac{r_0}{r_{ij}} \right ) ^{12} -
\frac{1}{2} \left ( \frac{r_0}{r_{ij}} \right ) ^{6} \right]
Args:
epsilon (Tensor): Tensor of shape `(...)`. Data type is float.
Well depth :math:`\epsilon`.
r_0 (Tensor): Tensor of shape `(...)`. Data type is float.
Atomic radius :math:`r_0`.
r_ij (Tensor): Tensor of shape `(...)`. Data type is float.
Distance :math:`r_{ij}` between atoms :math:`i` and :math:`i`.
mask (Tensor): Tensor of shape `(...)`. Data type is bool.
Mask for distances :math:`r_{ij}`. Default: ``None``.
Returns:
E_coulomb (Tensor): Tensor of shape `(...)`. Data type is float.
Supported Platforms:
``Ascend`` ``GPU``
"""
# (\r_0 / r_{ij}) ^ 6
r0_6 = F.pows(r_0 * msnp.reciprocal(r_ij), 6)
# 2 * \epsilon * (r_0 / r_{ij}) ^ 6
ene_bcoeff = 2 * epsilon * r0_6
# \epsilon * (r_0 / r_{ij}) ^ 12
ene_acoeff = epsilon * r0_6 * r0_6
energy = ene_acoeff - ene_bcoeff
if mask is None:
return energy
return energy * mask
[文档]def get_integer(value: Union[int, Tensor, Parameter, ndarray]) -> int:
r"""get integer type of the input value
Args:
value (Union[int, Tensor, Parameter, ndarray]): Input value
Returns:
integer (int)
Supported Platforms:
``Ascend`` ``GPU`` ``CPU``
"""
if value is None:
return None
if isinstance(value, Tensor):
value = value.asnumpy()
return int(value)
[文档]def get_ndarray(value: Union[Tensor, Parameter, ndarray, List[float], Tuple[float]],
dtype: type = None) -> ndarray:
r"""get ndarray type of the input value
Args:
value (Union[Tensor, Parameter, ndarray, List[float], Tuple[float]]): Input value
dtype (type): Data type. Default: ``None``.
Returns:
array (ndarray)
Supported Platforms:
``Ascend`` ``GPU`` ``CPU``
"""
if value is None:
return None
if isinstance(value, (Tensor, Parameter)):
value = value.asnumpy()
if dtype is not None:
value = value.astype(dtype)
else:
value = np.array(value, dtype)
return value
def get_tensor(value: Union[float, int, Tensor, Parameter, ndarray, List[float], Tuple[float]],
dtype: type = None) -> Tensor:
r"""get mindspore.Tensor type of the input value
Args:
value (Union[float, int, Tensor, Parameter, ndarray, list, tuple]):
Input value
dtype (type): Data type. Default: ``None``.
Returns:
tensor (Tensor)
Supported Platforms:
``Ascend`` ``GPU`` ``CPU``
"""
if value is None:
return None
if isinstance(value, ndarray):
value = Tensor(value, dtype)
elif isinstance(value, Parameter):
value = identity(value)
elif not isinstance(value, Tensor):
(value,) = _to_tensor((value,))
if dtype is not None and dtype != value.dtype:
value = F.cast(value, dtype)
return value
def get_ms_array(value: Union[float, int, Tensor, Parameter, ndarray, list, tuple],
dtype: type = None
) -> Union[Tensor, Parameter]:
r"""get mindspore.Tensor type of the input value
Args:
value (Union[float, int, Tensor, Parameter, ndarray, list, tuple]):
Input value
dtype (type): Data type. Default: ``None``.
Returns:
array (Tensor or Parameter)
Supported Platforms:
``Ascend`` ``GPU`` ``CPU``
"""
if value is None:
return None
if isinstance(value, ndarray):
value = Tensor(value, dtype)
elif not isinstance(value, (Tensor, Parameter)):
(value,) = _to_tensor((value,))
if dtype is not None and value.dtype != dtype:
value = F.cast(value, dtype)
return value
def check_broadcast(shape0: tuple, shape1: tuple) -> tuple:
r"""Check whether the two shapes match the rule of broadcast.
Args:
shape0 (tuple): First shape
shape1 (tuple): Second shape
Returns:
shape (tuple): Shape after broadcast
Supported Platforms:
``Ascend`` ``GPU`` ``CPU``
"""
if shape0 is None:
return shape1
if shape1 is None:
return shape0
if len(shape0) < len(shape1):
shape0 = (1,) * (len(shape1) - len(shape0)) + shape0
if len(shape0) > len(shape1):
shape1 = (1,) * (len(shape0) - len(shape1)) + shape1
shape = ()
for s0, s1 in zip(shape0, shape1):
if s0 == s1:
s = s0
else:
if s0 == 1:
s = s1
elif s1 == 1:
s = s0
else:
raise ValueError(f'{shape0} and {shape1} cannot be broadcast to each other!')
shape += (s,)
return shape
def any_none(iterable: Iterable) -> bool:
r"""Return True if ANY values x in the iterable is None.
Args:
iterable (Iterable): Iterable variable
Returns:
any (bool): If any values x in the iterable is None
Supported Platforms:
``Ascend`` ``GPU`` ``CPU``
"""
return any([i is None for i in iterable])
def all_none(iterable: Iterable) -> bool:
r"""Return True if ALL values `x` in the `iterable` is None..
Args:
iterable (Iterable): Iterable variable
Returns:
all (bool): If all values `x` in the `iterable` is None
Supported Platforms:
``Ascend`` ``GPU`` ``CPU``
"""
return all([i is None for i in iterable])
def any_not_none(iterable: Iterable) -> bool:
r"""Return True if ANY values `x` in the `iterable` is NOT None.
Args:
iterable (Iterable): Iterable variable
Returns:
any (bool): If any values `x` in the `iterable` is not None
Supported Platforms:
``Ascend`` ``GPU`` ``CPU``
"""
return any([i is not None for i in iterable])
def all_not_none(iterable: Iterable) -> bool:
r"""Return True if ALL values `x` in the `iterable` is Not None.
Args:
iterable (Iterable): Iterable variable
Returns:
all (bool): If all values `x` in the `iterable` is Not None
Supported Platforms:
``Ascend`` ``GPU`` ``CPU``
"""
return all([i is not None for i in iterable])
def get_arguments(locals_: dict, kwargs: dict = None) -> dict:
r"""get arguments of a class
Args:
locals_ (dict): Dictionary of the arguments from `locals()`.
kwargs (dict): Dictionary of keyword arguments (kwargs) of the class.
Returns:
args (dict): Dictionary of arguments
Supported Platforms:
``Ascend`` ``GPU`` ``CPU``
"""
if '__class__' in locals_.keys():
locals_.pop('__class__')
arguments = {}
if 'self' in locals_.keys():
cls = locals_.pop('self')
arguments['cls_name'] = cls.__class__.__name__
def _set_arguments(args_: dict):
def _convert(value):
if value is None or isinstance(value, (int, float, bool, str,
time, timedelta, date)):
return value
if isinstance(value, ndarray):
return value.tolist()
if isinstance(value, (Tensor, Parameter)):
return value.asnumpy().tolist()
if isinstance(value, (list, tuple)):
return [_convert(v) for v in value]
if isinstance(value, dict):
if 'cls_name' in value.keys():
return value
dict_ = value.copy()
for k, v in value.items():
dict_[k] = _convert(v)
return dict_
cls_name = value.__class__.__name__
if hasattr(value, '_kwargs'):
value = value.__dict__['_kwargs']
elif hasattr(value, 'init_args'):
value = value.__dict__['init_args']
else:
value = value.__class__.__name__
if isinstance(value, dict) and 'cls_name' not in value.keys():
dict_ = {'cls_name': cls_name}
dict_.update(_set_arguments(value))
value = dict_
return value
for k, v in args_.items():
args_[k] = _convert(v)
return args_
kwargs_ = {}
if 'kwargs' in locals_.keys():
kwargs_: dict = locals_.pop('kwargs')
if kwargs is None:
kwargs = kwargs_
if 'cls_name' in kwargs.keys():
kwargs.pop('cls_name')
arguments.update(_set_arguments(locals_))
arguments.update(_set_arguments(kwargs))
return arguments
def get_initializer(cls_name: Union[Initializer, str, dict, Tensor], **kwargs) -> Initializer:
r"""get initializer by name
Args:
cls_name (Union[Initializer, str, dict, Tensor]): Class name of Initializer.
kwargs (dict): Dictionary of keyword arguments (kwargs) of the class.
Returns:
Initializer
Supported Platforms:
``Ascend`` ``GPU`` ``CPU``
"""
if isinstance(cls_name, Initializer):
return cls_name
if isinstance(cls_name, (Tensor, Parameter, ndarray)):
return get_tensor(cls_name, ms.float32)
if isinstance(cls_name, dict):
return get_initializer(**cls_name)
if isinstance(cls_name, str):
init = _INITIALIZER_ALIAS.get(cls_name.lower())
if init is None:
raise ValueError(f"For 'initializer', the class corresponding to '{cls_name}' was not found.")
return init(**kwargs)
raise TypeError(f'The cls_name must be Initializer, str, dict or Tensor but got: {init}')
def _bonds_in(bonds, bond):
""" Check bonds exists in both sets. """
return (bonds == bond).all(-1)
def bonds_in(bonds, batch_bond):
""" Return if batch_bond exists in bonds.
Args:
bonds: The total bonds set.
batch_bond: The input bond set.
Returns:
If batch_bond exists in bonds, the mask will be 1, else 0.
"""
return ops.vmap(_bonds_in, in_axes=(None, -2), out_axes=0)(bonds, batch_bond).sum(axis=-3)