PINA/pina/operators.py

"""Module for operators vectorize implementation"""
import torch

from pina.label_tensor import LabelTensor


def grad(output_, input_, components=None, d=None):
    """
    Perform gradient operation. The operator works for vectorial and scalar
    functions, with multiple input coordinates.

    :param LabelTensor output_: the output tensor onto which computing the
        gradient.
    :param LabelTensor input_: the input tensor with respect to which computing
        the gradient.
    :param list(str) components: the name of the output variables to calculate
        the gradient for. It should be a subset of the output labels. If None,
        all the output variables are considered. Default is None.
    :param list(str) d: the name of the input variables on which the gradient is
        calculated. d should be a subset of the input labels. If None, all the
        input variables are considered. Default is None.

    :return: the gradient tensor.
    :rtype: LabelTensor
    """

    def grad_scalar_output(output_, input_, d):
        """
        Perform gradient operation for a scalar output.

        :param LabelTensor output_: the output tensor onto which computing the
            gradient. It has to be a column tensor.
        :param LabelTensor input_: the input tensor with respect to which
            computing the gradient.
        :param list(str) d: the name of the input variables on which the
            gradient is calculated. d should be a subset of the input labels. If
            None, all the input variables are considered. Default is None.

        :raises RuntimeError: a vectorial function is passed.
        :raises RuntimeError: missing derivative labels.
        :return: the gradient tensor.
        :rtype: LabelTensor
        """

        if len(output_.labels) != 1:
            raise RuntimeError('only scalar function can be differentiated')
        if not all([di in input_.labels for di in d]):
            raise RuntimeError('derivative labels missing from input tensor')

        output_fieldname = output_.labels[0]
        gradients = torch.autograd.grad(
            output_,
            input_,
            grad_outputs=torch.ones(output_.size(), dtype=output_.dtype,
                                    device=output_.device),
            create_graph=True,
            retain_graph=True,
            allow_unused=True
        )[0]

        gradients.labels = input_.labels
        gradients = gradients.extract(d)
        gradients.labels = [f'd{output_fieldname}d{i}' for i in d]

        return gradients

    if not isinstance(input_, LabelTensor):
        raise TypeError

    if d is None:
        d = input_.labels

    if components is None:
        components = output_.labels

    if output_.shape[1] == 1:  # scalar output ################################

        if components != output_.labels:
            raise RuntimeError
        gradients = grad_scalar_output(output_, input_, d)

    elif output_.shape[1] >= 2:  # vector output ##############################

        for i, c in enumerate(components):
            c_output = output_.extract([c])
            if i == 0:
                gradients = grad_scalar_output(c_output, input_, d)
            else:
                gradients = gradients.append(
                    grad_scalar_output(c_output, input_, d))
    else:
        raise NotImplementedError

    return gradients


def div(output_, input_, components=None, d=None):
    """
    Perform divergence operation. The operator works for vectorial functions,
    with multiple input coordinates.

    :param LabelTensor output_: the output tensor onto which computing the
        divergence.
    :param LabelTensor input_: the input tensor with respect to which computing
        the divergence.
    :param list(str) components: the name of the output variables to calculate
        the divergence for. It should be a subset of the output labels. If None,
        all the output variables are considered. Default is None.
    :param list(str) d: the name of the input variables on which the divergence
        is calculated. d should be a subset of the input labels. If None, all
        the input variables are considered. Default is None.

    :raises TypeError: div operator works only for LabelTensor.
    :raises ValueError: div operator works only for vector fields.
    :raises ValueError: div operator must derive all components with
        respect to all coordinates.
    :return: the divergenge tensor.
    :rtype: LabelTensor
    """
    if not isinstance(input_, LabelTensor):
        raise TypeError

    if d is None:
        d = input_.labels

    if components is None:
        components = output_.labels

    if output_.shape[1] < 2 or len(components) < 2:
        raise ValueError('div supported only for vector fields')

    if len(components) != len(d):
        raise ValueError

    grad_output = grad(output_, input_, components, d)
    div = torch.zeros(input_.shape[0], 1, device=output_.device)
    labels = [None] * len(components)
    for i, (c, d) in enumerate(zip(components, d)):
        c_fields = f'd{c}d{d}'
        div[:, 0] += grad_output.extract(c_fields).sum(axis=1)
        labels[i] = c_fields

    div = div.as_subclass(LabelTensor)
    div.labels = ['+'.join(labels)]
    return div


def laplacian(output_, input_, components=None, d=None, method='std'):
    """
    Compute Laplace operator. The operator works for vectorial and
    scalar functions, with multiple input coordinates.

    :param LabelTensor output_: the output tensor onto which computing the
        Laplacian.
    :param LabelTensor input_: the input tensor with respect to which computing
        the Laplacian.
    :param list(str) components: the name of the output variables to calculate
        the Laplacian for. It should be a subset of the output labels. If None,
        all the output variables are considered. Default is None.
    :param list(str) d: the name of the input variables on which the Laplacian
        is calculated. d should be a subset of the input labels. If None, all
        the input variables are considered. Default is None.
    :param str method: used method to calculate Laplacian, defaults to 'std'.
    :raises ValueError: for vectorial field derivative with respect to
        all coordinates must be performed.
    :raises NotImplementedError: 'divgrad' not implemented as method.
    :return: The tensor containing the result of the Laplacian operator.
    :rtype: LabelTensor
    """
    if d is None:
        d = input_.labels

    if components is None:
        components = output_.labels

    if len(components) != len(d) and len(components) != 1:
        raise ValueError

    if method == 'divgrad':
        raise NotImplementedError('divgrad not implemented as method')
        # TODO fix
        # grad_output = grad(output_, input_, components, d)
        # result = div(grad_output, input_, d=d)
    elif method == 'std':

        if len(components) == 1:
            grad_output = grad(output_, input_, components=components, d=d)
            result = torch.zeros(output_.shape[0], 1, device=output_.device)
            for i, label in enumerate(grad_output.labels):
                gg = grad(grad_output, input_, d=d, components=[label])
                result[:, 0] += super(torch.Tensor, gg.T).__getitem__(i) # TODO improve
            labels = [f'dd{components[0]}']

        else:
            result = torch.empty(input_.shape[0], len(components),
                                 device=output_.device)
            labels = [None] * len(components)
            for idx, (ci, di) in enumerate(zip(components, d)):

                if not isinstance(ci, list):
                    ci = [ci]
                if not isinstance(di, list):
                    di = [di]

                grad_output = grad(output_, input_, components=ci, d=di)
                result[:, idx] = grad(grad_output, input_, d=di).flatten()
                labels[idx] = f'dd{ci}dd{di}'

    result = result.as_subclass(LabelTensor)
    result.labels = labels
    return result


def advection(output_, input_, velocity_field, components=None, d=None):
    """
    Perform advection operation. The operator works for vectorial functions,
    with multiple input coordinates.

    :param LabelTensor output_: the output tensor onto which computing the
        advection.
    :param LabelTensor input_: the input tensor with respect to which computing
        the advection.
    :param str velocity_field: the name of the output variables which is used
        as velocity field. It should be a subset of the output labels.
    :param list(str) components: the name of the output variables to calculate
        the Laplacian for. It should be a subset of the output labels. If None,
        all the output variables are considered. Default is None.
    :param list(str) d: the name of the input variables on which the advection
        is calculated. d should be a subset of the input labels. If None, all
        the input variables are considered. Default is None.
    :return: the tensor containing the result of the advection operator.
    :rtype: LabelTensor
    """
    if d is None:
        d = input_.labels

    if components is None:
        components = output_.labels

    tmp = grad(output_, input_, components, d
               ).reshape(-1, len(components), len(d)).transpose(0, 1)

    tmp *= output_.extract(velocity_field)
    return tmp.sum(dim=2).T