# Copyright 2021 Huawei Technologies Co., Ltd
#
# 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,
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# ============================================================================
"""RootMeanSquareSurfaceDistance."""
from __future__ import absolute_import

from scipy.ndimage import morphology
import numpy as np

from mindspore import _checkparam as validator
from mindspore.train.metrics.metric import Metric, rearrange_inputs


class RootMeanSquareDistance(Metric):
    r"""
    Computes the Root Mean Square Surface Distance from `y_pred` to `y` under the default setting.

    Given two sets A and B, S(A) denotes the set of surface voxels of A, the shortest distance of an
    arbitrary voxel v to S(A) is defined as:

    .. math::
        {\text{dis}}\left (v, S(A)\right ) = \underset{s_{A}  \in S(A)}{\text{min }}\rVert v - s_{A} \rVert

    The Root Mean Square Surface Distance from set(B) to set(A) is:

    .. math::
        RmsSurDis(B \rightarrow A) = \sqrt{\frac{\sum_{s_{B}  \in S(B)}^{} {\text{dis}^2  \left ( s_{B}, S(A)
        \right )} }{\left | S(B) \right |}}

    Where the \|\|\*\|\| denotes a distance measure. \|\*\| denotes the number of elements.

    The Root Mean Square Surface Distance from set(B) to set(A) and from set(A) to set(B) is:

    .. math::
        RmsSurDis(A \leftrightarrow B) = \sqrt{\frac{\sum_{s_{A}  \in S(A)}^{} {\text{dis}  \left ( s_{A},
        S(B) \right ) ^{2}} + \sum_{s_{B} \in S(B)}^{} {\text{dis}  \left ( s_{B}, S(A) \right ) ^{2}}}{\left | S(A)
        \right | + \left | S(B) \right |}}

    Args:
        distance_metric (string): Three measurement methods are supported:
                ``"euclidean"`` (Euclidean Distance) ,  ``"chessboard"`` (Chessboard Distance, Chebyshev Distance)
                or  ``"taxicab"`` (Taxicab Distance, Manhattan Distance). Default: ``"euclidean"`` .
        symmetric (bool):  Whether to calculate the symmetric average root mean square distance between
                y_pred and y. If False, only calculates :math:`RmsSurDis(y\_pred, y)` surface distance,
                otherwise, the mean of  distance from `y_pred` to `y` and from `y` to `y_pred`, i.e.
                :math:`RmsSurDis(y\_pred \leftrightarrow y)` will be returned. Default: ``False`` .

    Supported Platforms:
        ``Ascend`` ``GPU`` ``CPU``

    Examples:
        >>> import numpy as np
        >>> from mindspore import Tensor
        >>> from mindspore.train import RootMeanSquareDistance
        >>>
        >>> x = Tensor(np.array([[3, 0, 1], [1, 3, 0], [1, 0, 2]]))
        >>> y = Tensor(np.array([[0, 2, 1], [1, 2, 1], [0, 0, 1]]))
        >>> metric = RootMeanSquareDistance(symmetric=False, distance_metric="euclidean")
        >>> metric.clear()
        >>> metric.update(x, y, 0)
        >>> root_mean_square_distance = metric.eval()
        >>> print(root_mean_square_distance)
        1.0000000000000002

    """

    def __init__(self, symmetric=False, distance_metric="euclidean"):
        super(RootMeanSquareDistance, self).__init__()
        self.distance_metric_list = ["euclidean", "chessboard", "taxicab"]
        distance_metric = validator.check_value_type("distance_metric", distance_metric, [str])
        self.distance_metric = validator.check_string(distance_metric, self.distance_metric_list, "distance_metric")
        self.symmetric = validator.check_value_type("symmetric", symmetric, [bool])
        self.clear()
        self._y_pred_edges = None
        self._is_update = None
        self._y_edges = None

    def _get_surface_distance(self, y_pred_edges, y_edges):
        """
        Calculate the surface distances from `y_pred_edges` to `y_edges`.

         Args:
            y_pred_edges (np.ndarray): the edge of the predictions.
            y_edges (np.ndarray): the edge of the ground truth.
        """
        if not np.any(y_pred_edges):
            return np.array([])
        if not np.any(y_edges):
            dis = np.full(y_edges.shape, np.inf)
        else:
            if self.distance_metric == "euclidean":
                dis = morphology.distance_transform_edt(~y_edges)
            elif self.distance_metric in self.distance_metric_list[-2:]:
                dis = morphology.distance_transform_cdt(~y_edges, metric=self.distance_metric)

        return dis[y_pred_edges]

    def clear(self):
        """Clears the internal evaluation result."""
        self._y_pred_edges = 0
        self._y_edges = 0
        self._is_update = False

    @rearrange_inputs
    def update(self, *inputs):
        """
        Updates the internal evaluation result 'y_pred', 'y' and 'label_idx'.

        Args:
            inputs: Input 'y_pred', 'y' and 'label_idx'. 'y_pred' and 'y' are `Tensor`, list or numpy.ndarray.
                    'y_pred' is the predicted binary image. 'y' is the actual binary image. 'label_idx', the data
                    type of `label_idx` is int.

        Raises:
            ValueError: If the number of the inputs is not 3.
            TypeError: If the data type of label_idx is not int or float.
            ValueError: If the value of label_idx is not in y_pred or y.
            ValueError: If y_pred and y have different shapes.
        """
        if len(inputs) != 3:
            raise ValueError("For 'RootMeanSquareDistance.update', it needs 3 inputs"
                             "(predicted value, true value, label index), but got {}.".format(len(inputs)))
        y_pred = self._convert_data(inputs[0])
        y = self._convert_data(inputs[1])
        label_idx = inputs[2]

        if not isinstance(label_idx, (int, float)):
            raise TypeError("For 'RootMeanSquareDistance.update', the label index (input[2]) must be int or float, "
                            "but got label index type: {}.".format(type(label_idx)))
        if label_idx not in y_pred and label_idx not in y:
            raise ValueError("For 'RootMeanSquareDistance.update', the label index (input[2]) "
                             "should be in predicted value (input[0]) or true value (input[1]), "
                             "but {} is not.".format(label_idx))
        if y_pred.size == 0 or y_pred.shape != y.shape:
            raise ValueError("For 'RootMeanSquareDistance.update', the size of predicted value (input[0]) "
                             "and true value (input[1]) should be greater than 0, in addition to that, "
                             "predicted value and true value should have the same shape, "
                             "but got predicted value size: {}, shape: {}, true value size: {}, shape: {}. "
                             .format(y_pred.size, y_pred.shape, y.size, y.shape))
        if y_pred.dtype != bool:
            y_pred = y_pred == label_idx
        if y.dtype != bool:
            y = y == label_idx

        self._y_pred_edges = morphology.binary_erosion(y_pred) ^ y_pred
        self._y_edges = morphology.binary_erosion(y) ^ y
        self._is_update = True

    def eval(self):
        """
        Calculate Root Mean Square Distance.

        Returns:
             numpy.float64, root mean square surface distance.

        Raises:
            RuntimeError: If the update method is not called first, an error will be reported.

        """
        if self._is_update is False:
            raise RuntimeError("Please call the 'update' method before calling 'eval' method.")

        residual_mean_square_distance = self._get_surface_distance(self._y_pred_edges, self._y_edges)

        if residual_mean_square_distance.shape == (0,):
            return np.inf

        rms_surface_distance = (residual_mean_square_distance ** 2).mean()

        if not self.symmetric:
            return rms_surface_distance

        contrary_residual_mean_square_distance = self._get_surface_distance(self._y_edges, self._y_pred_edges)
        if contrary_residual_mean_square_distance.shape == (0,):
            return np.inf

        contrary_rms_surface_distance = (contrary_residual_mean_square_distance ** 2).mean()

        rms_distance = np.sqrt(np.mean((rms_surface_distance, contrary_rms_surface_distance)))
        return rms_distance