mindspore.nn.layer.pooling 源代码

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"""pooling"""
from __future__ import absolute_import

from mindspore.ops import operations as P
from mindspore.ops import functional as F
import mindspore.ops as ops
from mindspore._checkparam import _check_3d_int_or_tuple
from mindspore import _checkparam as validator
from mindspore.ops.primitive import constexpr, _primexpr
from mindspore.common.tensor import Tensor
import mindspore.context as context
from mindspore.common import dtype as mstype
from mindspore.ops.operations.nn_ops import AdaptiveMaxPool2D
from mindspore.ops.operations.nn_ops import AdaptiveMaxPool3D, AdaptiveAvgPool3D
from mindspore.nn.cell import Cell

__all__ = ['AvgPool3d', 'MaxPool3d', 'AvgPool2d', 'MaxPool2d', 'AvgPool1d', 'MaxPool1d', 'FractionalMaxPool2d',
           'FractionalMaxPool3d', 'AdaptiveAvgPool1d', 'AdaptiveMaxPool1d', 'AdaptiveMaxPool2d', 'AdaptiveMaxPool3d',
           'AdaptiveAvgPool2d', 'AdaptiveAvgPool3d', 'MaxUnpool1d', 'MaxUnpool2d', 'MaxUnpool3d', 'LPPool1d',
           'LPPool2d']


class _PoolNd(Cell):
    """N-D  AvgPool"""

    def __init__(self, kernel_size, stride, pad_mode, data_format="NCHW"):
        """Initialize _PoolNd."""
        super(_PoolNd, self).__init__()
        validator.check_value_type('pad_mode', pad_mode, [str], self.cls_name)
        self.pad_mode = validator.check_string(pad_mode.upper(), ['VALID', 'SAME', 'PAD'], 'pad_mode', self.cls_name)
        self.format = validator.check_string(data_format, ['NCHW', 'NHWC'], 'format', self.cls_name)
        if context.get_context("device_target") != "GPU" and self.format == "NHWC":
            raise ValueError(f"For '{self.cls_name}, the 'NHWC' format only support in GPU target, but got device "
                             f"target {context.get_context('device_target')}.")

        def _check_int_or_tuple(arg_name, arg_value):
            validator.check_value_type(arg_name, arg_value, [int, tuple], self.cls_name)
            error_msg = f"For '{self.cls_name}', the '{arg_name}' must be an positive int number or " \
                        f"a tuple, but got {arg_value}"
            if isinstance(arg_value, int):
                if arg_value <= 0:
                    raise ValueError(error_msg)
            else:
                for item in arg_value:
                    if isinstance(item, int) and item > 0:
                        continue
                    raise ValueError(error_msg)
                if len(arg_value) == 1:
                    return arg_value[0]
            return arg_value

        self.kernel_size = _check_int_or_tuple('kernel_size', kernel_size)
        self.stride = _check_int_or_tuple('stride', stride)

    def construct(self, *inputs):
        pass

    def extend_repr(self):
        return 'kernel_size={kernel_size}, stride={stride}, pad_mode={pad_mode}'.format(**self.__dict__)


@_primexpr
def _shape_check(in_shape, prim_name=None):
    msg_prefix = f"For '{prim_name}', the" if prim_name else "The"

    def _check():
        if len(in_shape) != 3:
            raise ValueError(f"{msg_prefix} input must has 3 dim, but got {len(in_shape)}")

    _check()


[文档]class LPPool1d(Cell): r""" Applying 1D LPPooling operation on an input Tensor can be regarded as forming a 1D input plane. Typically the input is of shape :math:`(N_{in}, C_{in}, L_{in})` or :math:`(C_{in}, L_{in})``, the output is of shape :math:`(N_{out}, C_{out}, L_{out})` or :math:`(C_{out}, L_{out})`, with the same shape as input, the operation is as follows. .. math:: f(X) = \sqrt[p]{\sum_{x \in X} x^{p}} Args: norm_type (Union[int, float]): Type of normalization, represents p in the formula, can not be 0. - if p = 1, the result is the sum of the elements within the pooling kernel(proportional to average pooling). - if p = :math:`\infty`, the result is the result of maximum pooling. kernel_size (int): The size of kernel window. stride (int): The distance of kernel moving, an int number that represents the width of movement is stride. If the value is None, the default value `kernel_size` is used. Default: None. ceil_mode (bool): Whether to use ceil or floor to calculate output shape. Default: False. Inputs: - **x** (Tensor) - Tensor of shape :math:`(N_{in}, C_{in}, L_{in})` or :math:`(C_{in}, L_{in})`. Outputs: - **output** (Tensor) - LPPool1d result, with shape :math:`(N_{out}, C_{out}, L_{out})` or :math:`(C_{out}, L_{out})`, it has the same data type as `x`, where .. math:: L_{out} = \left\lfloor\frac{L_{in} - \text{kernel_size}}{\text{stride}} + 1\right\rfloor Raises: TypeError: If `x` is not an Tensor. TypeError: If `kernel_size` or `stride` is not an int. TypeError: If `ceil_mode` is not a bool. TypeError: If `norm_type` is neither float nor int. ValueError: If `norm_type` is equal to 0. ValueError: If `kernel_size` or `stride` is less than 1. ValueError: If length of shape of `x` is not equal to 2 or 3. Supported Platforms: ``Ascend`` ``GPU`` ``CPU`` Examples: >>> import mindspore as ms >>> import mindspore.nn as nn >>> from mindspore import Tensor >>> import numpy as np >>> a = Tensor(np.arange(2 * 3 * 4).reshape((2, 3, 4)), dtype=ms.float32) >>> net = nn.LPPool1d(norm_type=1, kernel_size=3, stride=1) >>> out = net(a) >>> print(out) [[[ 3. 6.] [15. 18.] [27. 30.]] [[39. 42.] [51. 54.] [63. 66.]]] """ def __init__(self, norm_type, kernel_size, stride=None, ceil_mode=False): super(LPPool1d, self).__init__() self.norm_type = norm_type self.kernel_size = kernel_size self.stride = stride self.ceil_mode = ceil_mode def construct(self, x): return ops.lp_pool1d(x, self.norm_type, self.kernel_size, self.stride, self.ceil_mode)
[文档]class LPPool2d(Cell): r""" Applying 2D LPPooling operation on an input Tensor can be regarded as forming a 1D input plane. Typically the input is of shape :math:`(N, C, H_{in}, W_{in})`, the output is of shape :math:`(N, C, H_{in}, W_{in})`, with the same shape as input, the operation is as follows. .. math:: f(X) = \sqrt[p]{\sum_{x \in X} x^{p}} Args: norm_type(Union[int, float]) - Type of normalization, represents p in the formula, can not be 0. - if p = 1, the result is the sum of the elements within the pooling kernel(proportional to average pooling). - if p = :math:`\infty`, the result is the result of maximum pooling. kernel_size(Union[int, tuple[int]]): The size of kernel window. The data type of kernel_size must be int and the value represents the height and width, or a tuple of two int numbers that represent height and width respectively. stride(Union[int, tuple[int]]): The distance of kernel moving, an int number that represents the height and width of movement are both stride, or a tuple of two int numbers that represent height and width of movement respectively, if the value is None, the default value `kernel_size` is used. Default: None. ceil_mode(bool): Whether to use ceil or floor to calculate output shape. Default: False. Inputs: - **x** (Tensor) - Tensor of shape :math:`(N, C, H_{in}, W_{in})`. Outputs: - **output** (Tensor) - LPPool2d result, with shape :math:`(N, C, H_{in}, W_{in})`, It has the same data type as `x`, where .. math:: H_{out} = \left\lfloor\frac{H_{in} - \text{kernel_size}[0]}{\text{stride}[0]} + 1\right\rfloor .. math:: W_{out} = \left\lfloor\frac{W_{in} - \text{kernel_size}[1]}{\text{stride}[1]} + 1\right\rfloor Raises: TypeError: If `x` is not an Tensor. TypeError: If `kernel_size` or `stride` is neither int nor tuple. TypeError: If `ceil_mode` is not a bool. TypeError: If `norm_type` is neither float nor int. ValueError: If `norm_type` is equal to 0. ValueError: If `kernel_size` or `stride` is less than 1. ValueError: If `kernel_size` or `stride` is a tuple whose length is not equal to `2`. ValueError: If length of shape of `x` is not equal to 4. Supported Platforms: ``Ascend`` ``GPU`` ``CPU`` Examples: >>> import mindspore as ms >>> import mindspore.nn as nn >>> from mindspore import Tensor >>> import numpy as np >>> a = Tensor(np.arange(2 * 3 * 4 * 5).reshape((2, 3, 4, 5)), dtype=ms.float32) >>> net = nn.LPPool2d(norm_type=1, kernel_size=3, stride=1) >>> out = net(a) >>> print(out) [[[[ 54. 63. 72.] [ 99. 108. 117.]] [[ 234. 243. 252.] [ 279. 288. 297.]] [[ 414. 423. 432.] [ 459. 468. 477.]]] [[[ 594. 603. 612.] [ 639. 648. 657.]] [[ 774. 783. 792.] [ 819. 828. 837.]] [[ 954. 963. 972.] [ 999. 1008. 1017.]]]] """ def __init__(self, norm_type, kernel_size, stride=None, ceil_mode=False): super(LPPool2d, self).__init__() self.norm_type = norm_type self.kernel_size = kernel_size self.stride = stride self.ceil_mode = ceil_mode def construct(self, x): return ops.lp_pool2d(x, self.norm_type, self.kernel_size, self.stride, self.ceil_mode)
def _check_maxpool_padding(padding, nd, cls_name): """Calculate maxpool padding before call primitive""" validator.check_value_type('padding', padding, (int, tuple, list), cls_name) if isinstance(padding, int): return (0,) * (3 - nd) + (padding,) * nd if isinstance(padding, (tuple, list)): validator.check_non_negative_int_sequence(padding, "padding", cls_name) if len(padding) == 1: return (0,) * (3 - nd) + tuple(padding * nd) if len(padding) != nd: raise ValueError(f"For {cls_name}, the length of padding must equal to {nd}, but got {len(padding)}.") return (0,) * (3 - nd) + tuple(padding) return padding def _cal_dilation(dilation, nd, cls_name): """check the dilation""" if isinstance(dilation, int): return dilation if isinstance(dilation, tuple): if len(dilation) == 1: return dilation[0] if len(dilation) == nd: return (3 - nd) * (1,) + dilation if nd == 1: raise ValueError(f"For {cls_name}, the length of 'dilation' must be 1, but got {len(dilation)}.") raise ValueError(f"For {cls_name}, the length of 'dilation' must be 1 or {nd}, but got {len(dilation)}.") raise ValueError(f"For {cls_name}, the 'dilation' must be int or tuple, but got {type(dilation)}.")
[文档]class MaxPool3d(_PoolNd): r""" 3D max pooling operation. Applies a 3D max pooling over an input Tensor which can be regarded as a composition of 3D planes. Typically the input is of shape :math:`(N_{in}, C_{in}, D_{in}, H_{in}, W_{in})`, MaxPool outputs regional maximum in the :math:`(D_{in}, H_{in}, W_{in})`-dimension. Given kernel size is :math:`ks = (d_{ker}, h_{ker}, w_{ker})` and stride is :math:`s = (s_0, s_1, s_2)`, the operation is as follows. .. math:: \text{output}(N_i, C_j, d, h, w) = \max_{l=0, \ldots, d_{ker}-1} \max_{m=0, \ldots, h_{ker}-1} \max_{n=0, \ldots, w_{ker}-1} \text{input}(N_i, C_j, s_0 \times d + l, s_1 \times h + m, s_2 \times w + n) Args: kernel_size (Union[int, tuple[int]]): The size of kernel used to take the maximum value, is an int number or a single element tuple that represents depth, height and width of the kernel, or a tuple of three int numbers that represent depth, height and width respectively. The value must be a positive integer. Default: 1. stride (Union[int, tuple[int]]): The moving stride of pooling operation, an int number or a single element tuple that represents the moving stride of pooling kernel in the directions of depth, height and the width, or a tuple of three int numbers that represent depth, height and width of movement respectively. The value must be a positive integer. If the value is None, the default value `kernel_size` is used. Default: 1. pad_mode (str): The optional value for pad mode, is "same", "valid" or "pad", not case sensitive. Default: "valid". - same: The output shape is the same as the input shape evenly divided by `stride`. - valid: The possible largest height and width of output will be returned without padding. Extra pixels will be discarded. - pad: pads the input. Pads the top, bottom, left, and right sides of the input with `padding` number of zeros. If this mode is set, `padding` must be greater than or equal to 0. padding (Union(int, tuple[int], list[int])): Pooling padding value. Default: 0. `padding` can only be an integer or a tuple/list containing one or three integers. If `padding` is an integer or a tuple/list containing one integer, it will be padded in six directions of front, back, top, bottom, left and right of the input. If `padding` is a tuple/list containing three integers, it will be padded in front and back of the input `padding[0]` times, up and down `padding[1]` times, and left and right of the input `padding[2]` times. dilation (Union(int, tuple[int])): The spacing between the elements of the kernel in convolution, used to increase the receptive field of the pooling operation. If it is a tuple, it must contain one or three integers. Default: 1. return_indices (bool): If True, output is a Tuple of 2 Tensors, representing the maxpool result and where the max values are generated. Otherwise, only the maxpool result is returned. Default: False. ceil_mode (bool): Whether to use ceil or floor to calculate output shape. Default: False. Inputs: - **x** (Tensor) - Tensor of shape :math:`(N_{in}, C_{in}, D_{in}, H_{in}, W_{in})` or :math:`(C_{in}, D_{in}, H_{in}, W_{in})`. Outputs: If `return_indices` is False, output is a Tensor, with shape :math:`(N_{out}, C_{out}, D_{out}, H_{out}, W_{out})` or :math:`(C_{out}, D_{out}, H_{out}, W_{out})`. It has the same data type as `x`. If `return_indices` is True, output is a Tuple of 2 Tensors, representing the maxpool result and where the max values are generated. - **output** (Tensor) - Maxpooling result, with shape :math:`(N_{out}, C_{out}, D_{out}, H_{out}, W_{out})` or :math:`(C_{out}, D_{out}, H_{out}, W_{out})`. It has the same data type as `x`. - **argmax** (Tensor) - Index corresponding to the maximum value. Data type is int64. If `pad_mode` is in `pad` mode, the output shape calculation formula is as follows: .. math:: D_{out} = \left\lfloor\frac{D_{in} + 2 \times \text{padding}[0] - \text{dilation}[0] \times (\text{kernel_size}[0] - 1) - 1}{\text{stride}[0]} + 1\right\rfloor .. math:: H_{out} = \left\lfloor\frac{H_{in} + 2 \times \text{padding}[1] - \text{dilation}[1] \times (\text{kernel_size}[1] - 1) - 1}{\text{stride}[1]} + 1\right\rfloor .. math:: W_{out} = \left\lfloor\frac{W_{in} + 2 \times \text{padding}[2] - \text{dilation}[2] \times (\text{kernel_size}[2] - 1) - 1}{\text{stride}[2]} + 1\right\rfloor Raises: ValueError: If length of shape of `x` is not equal to 4 or 5. TypeError: If `kernel_size` , `stride` , `padding` or `dilation` is neither an int nor a tuple. ValueError: If `kernel_size` or `stride` is less than 1. ValueError: If the `padding` parameter is neither an integer nor a tuple of length 3. ValueError: If `pad_mode` is not set to 'pad', setting return_indices to True or dilation to a value other than 1. ValueError: If `padding` is non-zero when `pad_mode` is not 'pad'. Supported Platforms: ``Ascend`` ``GPU`` ``CPU`` Examples: >>> import mindspore as ms >>> import mindspore.nn as nn >>> import numpy as np >>> np_x = np.random.randint(0, 10, [5, 3, 4, 6, 7]) >>> x = Tensor(np_x, ms.float32) >>> pool1 = nn.MaxPool3d(kernel_size=2, stride=1, pad_mode='pad', padding=1, dilation=3, return_indices=True) >>> output = pool1(x) >>> print(output[0].shape) (5, 3, 3, 5, 6) >>> print(output[1].shape) (5, 3, 3, 5, 6) >>> pool2 = nn.MaxPool3d(kernel_size=2, stride=1, pad_mode='pad', padding=1, dilation=3, return_indices=False) >>> output2 = pool2(x) >>> print(output2.shape) (5, 3, 3, 5, 6) """ def __init__(self, kernel_size=1, stride=1, pad_mode="valid", padding=0, dilation=1, return_indices=False, ceil_mode=False): """Initialize MaxPool3d.""" super(MaxPool3d, self).__init__(kernel_size, stride, pad_mode) self.return_indices = return_indices padding = _check_maxpool_padding(padding, 3, self.cls_name) _check_3d_int_or_tuple("padding", padding, self.cls_name, greater_zero=False, ret_five=False) if dilation != 1 or return_indices: self.only_pad = True if pad_mode.upper() != "PAD": raise ValueError(f"For {self.cls_name}, the pad_mode must be 'pad' when dilation is not 1 " f"or return_indices is True, but got pad_mode:{pad_mode}.") self.max_pool = P.MaxPool3DWithArgmax(ksize=kernel_size, strides=stride, pads=padding, dilation=dilation, ceil_mode=ceil_mode) else: self.only_pad = False ceil_mode = None if not ceil_mode else True self.max_pool = P.MaxPool3D(kernel_size=kernel_size, strides=stride, pad_mode=pad_mode, pad_list=padding, ceil_mode=ceil_mode) def construct(self, x): expand_batch = False if x.ndim == 4: x = x.unsqueeze(0) expand_batch = True out = self.max_pool(x) if expand_batch: if isinstance(out, tuple): out = (out[0].squeeze(0), out[1].squeeze(0)) else: out = out.squeeze(0) if self.only_pad and not self.return_indices: return out[0] return out
[文档]class MaxPool2d(_PoolNd): r""" Applies a 2D max pooling over an input Tensor which can be regarded as a composition of 2D planes. Typically the input is of shape :math:`(N_{in}, C_{in}, H_{in}, W_{in})`, MaxPool2d outputs regional maximum in the :math:`(H_{in}, W_{in})`-dimension. Given kernel size :math:`(h_{ker}, w_{ker})` and stride :math:`(s_0, s_1)`, the operation is as follows. .. math:: \text{output}(N_i, C_j, h, w) = \max_{m=0, \ldots, h_{ker}-1} \max_{n=0, \ldots, w_{ker}-1} \text{input}(N_i, C_j, s_0 \times h + m, s_1 \times w + n) Args: kernel_size (Union[int, tuple[int]]): The size of kernel used to take the max value, is an int number or a single element tuple that represents height and width are both kernel_size, or a tuple of two int numbers that represent height and width respectively. Default: 1. stride (Union[int, tuple[int]]): The distance of kernel moving, an int number or a single element tuple that represents the height and width of movement are both stride, or a tuple of two int numbers that represent height and width of movement respectively. Default: 1. pad_mode (str): The optional value for pad mode, is "same", "valid" or "pad", not case sensitive. Default: "valid". - same: The output shape is the same as the input shape evenly divided by `stride`. - valid: The possible largest height and width of output will be returned without padding. Extra pixels will be discarded. - pad: pads the input. Pads the top, bottom, left, and right sides of the input with `padding` number of zeros. If this mode is set, `padding` must be greater than or equal to 0. padding (Union(int, tuple[int], list[int])): Specifies the padding value of the pooling operation. Default: 0. `padding` can only be an integer or a tuple/list containing one or two integers. If `padding` is an integer or a tuple/list containing one integer, it will be padded `padding` times in the four directions of the input. If `padding` is a tuple/list containing two integers, it will be padded `padding[0]` times in the up-down direction of the input and `padding[1]` times in the left-right direction of the input. dilation (Union(int, tuple[int])): The spacing between the elements of the kernel in convolution, used to increase the receptive field of the pooling operation. If it is a tuple, it must contain one or two integers. Default: 1. return_indices (bool): If True, the function will return both the result of max pooling and the indices of the max elements. Default: False. ceil_mode (bool): If True, use ceil to compute the output shape instead of floor. Default: False. data_format (str): The optional value for data format, is 'NHWC' or 'NCHW'. Default: 'NCHW'. Inputs: - **x** (Tensor) - Tensor of shape :math:`(N,C_{in},H_{in},W_{in})` or :math:`(C_{in},H_{in},W_{in})`. Outputs: If `return_indices` is False, output is a Tensor, with shape :math:`(N, C, H_{out}, W_{out})` or :math:`(C_{out}, H_{out}, W_{out})`. It has the same data type as `x`. If `return_indices` is True, output is a Tuple of 2 Tensors, representing the maxpool result and where the max values are generated. - **output** (Tensor) - Maxpooling result, with shape :math:`(N_{out}, C_{out}, H_{out}, W_{out})` or :math:`(C_{out}, H_{out}, W_{out})`. It has the same data type as `x`. - **argmax** (Tensor) - Index corresponding to the maximum value. Data type is int64. If `pad_mode` is in `pad` mode, the output shape calculation formula is as follows: .. math:: H_{out} = \left\lfloor\frac{H_{in} + 2 * \text{padding[0]} - \text{dilation[0]} \times (\text{kernel_size[0]} - 1) - 1}{\text{stride[0]}} + 1\right\rfloor .. math:: W_{out} = \left\lfloor\frac{W_{in} + 2 * \text{padding[1]} - \text{dilation[1]} \times (\text{kernel_size[1]} - 1) - 1}{\text{stride[1]}} + 1\right\rfloor Raises: TypeError: If `kernel_size` or `stride` is neither int nor tuple. ValueError: If `pad_mode` is neither 'valid' nor 'same' with not case sensitive. ValueError: If `data_format` is neither 'NCHW' nor 'NHWC'. ValueError: If `kernel_size` or `stride` is less than 1. ValueError: If length of shape of `x` is not equal to 3 or 4. ValueError: If `pad_mode` is not 'pad', `padding`, `dilation`, `return_indices`, `ceil_mode` parameters are not set to their default values. ValueError: If the length of the tuple/list `padding` parameter is not 2. ValueError: If The length of the tuple dilation parameter is not 2. ValueError: If dilation parameter is neither an integer nor a tuple. ValueError: If `pad_mode` is 'pad' and `data_format` is 'NHWC'. ValueError: If `padding` is non-zero when `pad_mode` is not 'pad'. Supported Platforms: ``Ascend`` ``GPU`` ``CPU`` Examples: >>> pool = nn.MaxPool2d(kernel_size=3, stride=1) >>> x = Tensor(np.random.randint(0, 10, [1, 2, 4, 4]), mindspore.float32) >>> output = pool(x) >>> print(output.shape) (1, 2, 2, 2) >>> np_x = np.random.randint(0, 10, [5, 3, 4, 5]) >>> x = Tensor(np_x, mindspore.float32) >>> pool2 = nn.MaxPool2d(kernel_size=2, stride=1, pad_mode='pad', padding=1, dilation=1, return_indices=True) >>> output = pool2(x) >>> print(output[0].shape) (5, 3, 5, 6) >>> print(output[1].shape) (5, 3, 5, 6) """ def __init__(self, kernel_size=1, stride=1, pad_mode="valid", padding=0, dilation=1, return_indices=False, ceil_mode=False, data_format="NCHW"): """Initialize MaxPool2d.""" super(MaxPool2d, self).__init__(kernel_size, stride, pad_mode, data_format) self.return_indices = return_indices if pad_mode.upper() == 'PAD': if self.format == "NHWC": raise ValueError(f"For '{self.cls_name}, the 'NHWC' format are not support when 'pad_mode' is 'pad'.") self.use_pad = True if isinstance(self.kernel_size, tuple): _check_tuple_length(self.kernel_size, 'kernel_size', 2, self.cls_name) kernel_size = (1,) + self.kernel_size elif isinstance(self.kernel_size, int): kernel_size = (1, self.kernel_size, self.kernel_size) if isinstance(self.stride, tuple): _check_tuple_length(self.stride, 'stride', 2, self.cls_name) stride = (1,) + self.stride elif isinstance(self.stride, int): stride = (1, self.stride, self.stride) self.padding = _check_maxpool_padding(padding, 2, self.cls_name) dilation = _cal_dilation(dilation, 2, self.cls_name) self.max_pool = P.MaxPool3DWithArgmax(ksize=kernel_size, strides=stride, pads=self.padding, dilation=dilation, ceil_mode=ceil_mode) else: self.use_pad = False if padding != 0 or dilation != 1 or return_indices or ceil_mode: raise ValueError(f"For MaxPool1d, the parameter 'padding', 'dilation', 'return_indices', 'ceil_mode' " f"can not be set to non-default value when pad_mode is not 'pad', " f"but got pad_mode:{pad_mode}.") self.max_pool = P.MaxPool(kernel_size=self.kernel_size, strides=self.stride, pad_mode=self.pad_mode, data_format=self.format) def construct(self, x): expand_batch = False if x.ndim == 3: x = x.unsqueeze(0) expand_batch = True if self.use_pad: x = x.unsqueeze(2) out = self.max_pool(x) if isinstance(out, tuple): out = out[0].squeeze(2), out[1].squeeze(2) else: out = out.squeeze(2) else: out = self.max_pool(x) if expand_batch: if isinstance(out, tuple): out = (out[0].squeeze(0), out[1].squeeze(0)) else: out = out.squeeze(0) if self.use_pad and not self.return_indices: return out[0] return out
[文档]class MaxPool1d(_PoolNd): r""" Applies a 1D max pooling over an input Tensor which can be regarded as a composition of 1D planes. Typically the input is of shape :math:`(N_{in}, C_{in}, L_{in})`, MaxPool1d outputs regional maximum in the :math:`(L_{in})`-dimension. Given `kernel size` :math:`ks = (l_{ker})` and `stride` :math:`s = (s_0)`, the operation is as follows: .. math:: \text{output}(N_i, C_j, l) = \max_{n=0, \ldots, l_{ker}-1} \text{input}(N_i, C_j, s_0 \times l + n) Args: kernel_size (int): The size of kernel used to take the max value, Default: 1. stride (int): The distance of kernel moving, an int number that represents the width of movement is stride. Default: 1. pad_mode (str): The optional value for pad mode, is "same", "valid" or "pad", not case sensitive. Default: "valid". - same: Adopts the way of completion. The total number of padding will be calculated in horizontal and vertical directions and evenly distributed to top and bottom, left and right if possible. Otherwise, the last extra padding will be done from the bottom and the right side. - valid: Adopts the way of discarding. The possible largest height and width of output will be returned without padding. Extra pixels will be discarded. - pad: Performs padding on the input. Adds padding size of zeros to both ends of the input. If this mode is set, padding must be greater than or equal to 0. padding (Union(int, tuple[int], list[int])): Padding value for the pooling. Default value is 0. padding can only be an integer or a tuple/list containing a single integer, in which case padding times or padding[0] times are padded on both sides of the input. dilation (Union(int, tuple[int])): The spacing between the elements of the kernel in convolution, used to increase the receptive field of the pooling operation. If it is a tuple, its length can only be 1. Default: 1. return_indices (bool): If True, the function will return both the result of max pooling and the indices of the max elements. Default: False. ceil_mode (bool): If True, use ceil to compute the output shape instead of floor. Default: False. Inputs: - **x** (Tensor) - Tensor of shape :math:`(N, C_{in}, L_{in})` or :math:`(C_{in}, L_{in})`. Outputs: If `return_indices` is False, output is a Tensor, with shape :math:`(N, C_{out}, L_{out})` or :math:`(C_{out}, L_{out})`. It has the same data type as `x`. If `return_indices` is True, output is a Tuple of 2 Tensors, representing the maxpool result and where the max values are generated. - **output** (Tensor) - Maxpooling result, with shape :math:`(N, C_{out}, L_{out})` or :math:`(C_{out}, L_{out})`. It has the same data type as `x`. - **argmax** (Tensor) - Index corresponding to the maximum value. Data type is int64. If `pad_mode` is in `pad` mode, the output shape calculation formula is as follows: .. math:: L_{out} = \left\lfloor \frac{L_{in} + 2 \times \text{padding} - \text{dilation} \times (\text{kernel_size} - 1) - 1}{\text{stride}} + 1\right\rfloor Raises: TypeError: If `kernel_size` or `strides` is not an int. ValueError: If `pad_mode` is not 'valid', 'same' or 'pad', case-insensitive. ValueError: If `data_format` is neither 'NCHW' nor 'NHWC'. ValueError: If `kernel_size` or `strides` is less than 1. ValueError: If length of shape of `x` is not equal to 2 or 3. ValueError: If `pad_mode` is not 'pad', `padding`, `dilation`, `return_indices`, `ceil_mode` parameters are not set to their default values. ValueError: If the length of the tuple/list `padding` parameter is not 1. ValueError: If The length of the tuple dilation parameter is not 1. ValueError: If dilation parameter is neither an integer nor a tuple. ValueError: If `padding` is non-zero when `pad_mode` is not 'pad'. Supported Platforms: ``Ascend`` ``GPU`` ``CPU`` Examples: >>> mpool1 = nn.MaxPool1d(kernel_size=3, stride=1) >>> x = Tensor(np.random.randint(0, 10, [1, 2, 4]), mindspore.float32) >>> output = mpool1(x) >>> result = output.shape >>> print(result) (1, 2, 2) >>> np_x = np.random.randint(0, 10, [5, 3, 4]) >>> x = Tensor(np_x, mindspore.float32) >>> mpool2 = nn.MaxPool1d(kernel_size=2, stride=1, pad_mode='pad', padding=1, dilation=1, return_indices=True) >>> output = mpool2(x) >>> print(output[0].shape) (5, 3, 5) >>> print(output[1].shape) (5, 3, 5) """ def __init__(self, kernel_size=1, stride=1, pad_mode="valid", padding=0, dilation=1, return_indices=False, ceil_mode=False): """Initialize MaxPool1d.""" super(MaxPool1d, self).__init__(kernel_size, stride, pad_mode) validator.check_int(kernel_size, 1, validator.GE, "kernel_size", self.cls_name) validator.check_int(stride, 1, validator.GE, "stride", self.cls_name) self.kernel_size = (1, kernel_size) self.stride = (1, stride) self.return_indices = return_indices if pad_mode.upper() == "PAD": self.use_pad = True self.kernel_size = (1, 1, kernel_size) self.stride = (1, 1, stride) self.padding = _check_maxpool_padding(padding, 1, self.cls_name) dilation = _cal_dilation(dilation, 1, self.cls_name) self.max_pool = P.MaxPool3DWithArgmax(ksize=self.kernel_size, strides=self.stride, pads=self.padding, dilation=dilation, ceil_mode=ceil_mode) else: self.use_pad = False if padding != 0 or dilation != 1 or return_indices or ceil_mode: raise ValueError(f"For MaxPool1d, the parameter 'padding', 'dilation', 'return_indices', 'ceil_mode' " f"can not be set to non-default value when pad_mode is not 'pad', " f"but got pad_mode:{pad_mode}.") self.max_pool = P.MaxPool(kernel_size=self.kernel_size, strides=self.stride, pad_mode=self.pad_mode) self.shape = F.shape self.reduce_mean = P.ReduceMean(keep_dims=True) self.expand = P.ExpandDims() self.squeeze = P.Squeeze(2) def construct(self, x): expand_batch = False if x.ndim == 2: x = x.unsqueeze(0) expand_batch = True if self.use_pad: x = x.unsqueeze(2).unsqueeze(3) output = self.max_pool(x) if isinstance(output, tuple): output = output[0].squeeze(3).squeeze(2), output[1].squeeze(3).squeeze(2) else: output = output.squeeze(3).squeeze(2) else: _shape_check(self.shape(x), self.cls_name) x = self.expand(x, 2) output = self.max_pool(x) output = self.squeeze(output) if expand_batch: if isinstance(output, tuple): output = (output[0].squeeze(0), output[1].squeeze(0)) else: output = output.squeeze(0) if self.use_pad and not self.return_indices: return output[0] return output
def _cal_padding(padding, cls_name, nd): """Calculate padding before call primitive""" validator.check_value_type('padding', padding, (int, tuple, list), cls_name) if isinstance(padding, int): padding = (0, 0) * (3 - nd) + (padding,) * nd * 2 elif isinstance(padding, (tuple, list)): validator.check_non_negative_int_sequence(padding, "padding", cls_name) if len(padding) == nd: padding_start = (0, 0) * (3 - nd) padding_end = tuple(padding[i // 2] for i in range(nd * 2)) padding = padding_start + padding_end elif len(padding) == 1: padding = (0, 0) * (3 - nd) + tuple(padding * nd * 2) else: if nd == 1: raise ValueError(f"For {cls_name}, the padding must be a int or tuple/list contains one int, " f"but got tuple/list with length:{len(padding)}.") raise ValueError(f"For {cls_name}, the padding must be a int or tuple/list contains 1 or {nd} int, " f"but got tuple/list with length:{len(padding)}.") return padding def _check_tuple_length(arg_name, prim_name, length, cls_name): """check the tuple length""" if len(arg_name) != length: raise ValueError(f"For {cls_name}, the length of {prim_name} must be equal to {length}, " f"but got {len(arg_name)}.") return arg_name
[文档]class AvgPool3d(_PoolNd): r""" Applies a 3D average pooling over an input Tensor which can be regarded as a composition of 3D input planes. Typically, the input is of shape :math:`(N_{in}, C_{in}, D_{in}, H_{in}, W_{in})`, and AvgPool3D outputs regional average in the :math:`(D_{in}, H_{in}, W_{in})`-dimension. Given kernel size is :math:`ks = (d_{ker}, h_{ker}, w_{ker})` and stride :math:`s = (s_0, s_1, s_2)`, the operation is as follows. .. warning:: `kernel_size` is in the range [1, 255]. `stride` is in the range [1, 63]. .. math:: \text{output}(N_i, C_j, d, h, w) = \frac{1}{d_{ker} * h_{ker} * w_{ker}} \sum_{l=0}^{d_{ker}-1} \sum_{m=0}^{h_{ker}-1} \sum_{n=0}^{w_{ker}-1} \text{input}(N_i, C_j, s_0 \times d + l, s_1 \times h + m, s_2 \times w + n) Args: kernel_size (Union[int, tuple[int]], optional): The size of kernel used to take the average value, can be an int number or a single element tuple that represents depth, height and width, or a tuple of three positive integers that represent depth, height and width respectively. Default: 1. stride (Union[int, tuple[int]], optional): The distance of kernel moving, can be a positive int or a single element tuple that represents the depth, height and width of movement, or a tuple of three positive integers that represents depth, height and width of movement respectively. If the value is None, the default value `kernel_size` is used. Default: 1. pad_mode (str, optional): Specifies the padding method of pooling, optional values are "same", "valid" or "pad", case insensitive. Default: "valid". - same: The depth, height and width of the output is the same as the value after the input is divided by stride. - valid: Returns the output obtained by effective calculation without padding. The excess pixels that do not meet the calculation will be discarded. - pad: Pads the input. Fill the front, back, top, and bottom of the input with 0s of size `padding`. If this mode is set, `padding` must be greater than or equal to 0. padding (Union(int, tuple[int], list[int]), optional): Pooling padding value, only 'pad' mode can be set to non-zero. Default: 0. Only the following paddings are supported: - `padding` is an integer or a tuple/list containing one integer, it will be padded in six directions of front, back, top, bottom, left and right of the input. - `padding` is a tuple/list containing three integers, it will be padded in front and back of the input `padding[0]` times, up and down `padding[1]` times, and left and right of the input `padding[2]` times. ceil_mode (bool, optional): If True, use ceil to compute the output shape instead of floor. Default: False. count_include_pad (bool, optional): If True, averaging calculation will include the zero-padding. Default: True. divisor_override (int, optional): If it is specified as a non-zero parameter, this parameter will be used as the divisor in the average calculation. Otherwise, `kernel_size` will be used as the divisor. Default: None. Inputs: - **x** (Tensor) - Tensor of shape :math:`(N, C, D_{in}, H_{in}, W_{in})` or :math:`(C, D_{in}, H_{in}, W_{in})`. Currently support float16 and float32 data type. Outputs: Tensor, with shape :math:`(N, C, D_{out}, H_{out}, W_{out})` or :math:`(C, D_{out}, H_{out}, W_{out})`, with the same data type as `x`. If `pad_mode` is in `pad` mode, the output shape calculation formula is as follows: .. math:: D_{out} = \left\lfloor\frac{D_{in} + 2 \times \text{padding}[0] - \text{kernel_size}[0]}{\text{stride}[0]} + 1\right\rfloor .. math:: H_{out} = \left\lfloor\frac{H_{in} + 2 \times \text{padding}[1] - \text{kernel_size}[1]}{\text{stride}[1]} + 1\right\rfloor .. math:: W_{out} = \left\lfloor\frac{W_{in} + 2 \times \text{padding}[2] - \text{kernel_size}[2]}{\text{stride}[2]} + 1\right\rfloor Raises: TypeError: If `kernel_size` is neither an int nor a tuple. TypeError: If `stride` is neither an int nor a tuple. TypeError: If `padding` is neither an int nor a tuple/list. TypeError: If `ceil_mode` or `count_include_pad` is not a bool. TypeError: If `divisor_override` is not an int. ValueError: If numbers in `kernel_size` or `stride` are not positive. ValueError: If `kernel_size` or `stride` is a tuple whose length is not equal to 3. ValueError: If `padding` is a tuple/list whose length is neither 1 nor 3. ValueError: If element of `padding` is less than 0. ValueError: If length of shape of `x` is neither 4 nor 5. ValueError: If `divisor_override` is less than or equal to 0. ValueError: If `padding` is non-zero when `pad_mode` is not 'pad'. Supported Platforms: ``Ascend`` ``GPU`` ``CPU`` Examples: >>> import mindspore as ms >>> import mindspore.nn as nn >>> import mindspore.ops as ops >>> pool = nn.AvgPool3d(kernel_size=3, stride=1) >>> x = ops.randn(1, 2, 4, 4, 5).astype(ms.float32) >>> output = pool(x) >>> print(output.shape) (1, 2, 2, 2, 3) >>> x1 = ops.randn(6, 5, 7, 7, 5).astype(ms.float32) >>> pool2 = nn.AvgPool3d(4, stride=2, pad_mode='pad', padding=(2, 2, 1), divisor_override=10) >>> output2 = pool2(x1) >>> print(output2.shape) (6, 5, 4, 4, 2) """ def __init__(self, kernel_size=1, stride=1, pad_mode="valid", padding=0, ceil_mode=False, count_include_pad=True, divisor_override=None): """Initialize AvgPool3d.""" super(AvgPool3d, self).__init__(kernel_size, stride, pad_mode) padding = _cal_padding(padding, self.cls_name, 3) if divisor_override is not None and divisor_override <= 0: raise ValueError(f"For '{self.cls_name}', the 'divisor_override' must be > 0, but got {divisor_override}.") divisor_override = 0 if divisor_override is None else divisor_override self.avg_pool = P.AvgPool3D(self.kernel_size, self.stride, pad_mode, padding, ceil_mode, count_include_pad, divisor_override) def construct(self, x): expand_batch = False if len(x.shape) == 4: x = x.unsqueeze(0) expand_batch = True out = self.avg_pool(x) if expand_batch: out = out.squeeze(0) return out
[文档]class AvgPool2d(_PoolNd): r""" Applies a 2D average pooling over an input Tensor which can be regarded as a composition of 2D input planes. Typically the input is of shape :math:`(N_{in}, C_{in}, H_{in}, W_{in})`, AvgPool2d outputs regional average in the :math:`(H_{in}, W_{in})`-dimension. Given kernel size :math:`ks = (h_{ker}, w_{ker})` and stride :math:`s = (s_0, s_1)`, the operation is as follows: .. math:: \text{output}(N_i, C_j, h, w) = \frac{1}{h_{ker} * w_{ker}} \sum_{m=0}^{h_{ker}-1} \sum_{n=0}^{w_{ker}-1} \text{input}(N_i, C_j, s_0 \times h + m, s_1 \times w + n) Args: kernel_size (Union[int, tuple[int]]): The size of kernel used to take the average value. The data type of kernel_size must be int or a single element tuple and the value represents the height and width, or a tuple of two int numbers that represent height and width respectively. Default: 1. stride (Union[int, tuple[int]]): The distance of kernel moving, an int number or a single element tuple that represents the height and width of movement are both strides, or a tuple of two int numbers that represent height and width of movement respectively. Default: 1. pad_mode (str) - Specifies the padding method of pooling, optional values are "same", "valid" or "pad", case insensitive. Default: "valid". - same: The height and width of the output is the same as the value after the input is divided by stride. - valid: Returns the output obtained by effective calculation without padding. The excess pixels that do not meet the calculation will be discarded. - pad: pads the input. Pads the top, bottom, left, and right sides of the input with `padding` number of zeros. If this mode is set, `padding` must be greater than or equal to 0. padding (Union(int, tuple[int], list[int])): Pooling padding value, only 'pad' mode can be set to non-zero. Default: 0. `padding` can only be an integer or a tuple/list containing one or two integers. If `padding` is an integer or a tuple/list containing one integer, it will be padded `padding` times in the four directions of the input. If `padding` is a tuple/list containing two integers, it will be padded `padding[0]` times in the up-down direction of the input and `padding[1]` times in the left-right direction of the input. ceil_mode (bool): If True, use ceil to compute the output shape instead of floor. Default: False. count_include_pad (bool): If True, averaging calculation will include the zero-padding. Default: True. divisor_override (int): If it is specified as a non-zero parameter, this parameter will be used as the divisor in the average calculation. Otherwise, `kernel_size` will be used as the divisor. Default: None. data_format (str): The optional value for data format, is 'NHWC' or 'NCHW'. Default: 'NCHW'. Inputs: - **x** (Tensor) - Tensor of shape :math:`(N, C_{in}, H_{in}, W_{in})` or :math:`(C_{in}, H_{in}, W_{in})`. Outputs: Tensor of shape :math:`(N, C_{out}, H_{out}, W_{out})` or :math:`(C_{out}, H_{out}, W_{out})`. If `pad_mode` is in `pad` mode, the output shape calculation formula is as follows: .. math:: H_{out} = \left\lfloor\frac{H_{in} + 2 \times \text{padding}[0] - \text{kernel_size}[0]}{\text{stride}[0]} + 1\right\rfloor .. math:: W_{out} = \left\lfloor\frac{W_{in} + 2 \times \text{padding}[1] - \text{kernel_size}[1]}{\text{stride}[1]} + 1\right\rfloor Raises: TypeError: If `kernel_size` or `strides` is neither int nor tuple. ValueError: If `pad_mode` is not 'valid' ,'same' or 'pad' with not case sensitive. ValueError: If `data_format` is neither 'NCHW' nor 'NHWC'. ValueError: If `padding`, `ceil_mode`, `count_include_pad`, or `divisor_override` is used or `pad_mode` is `pad` when `data_format` is 'NHWC'. ValueError: If `kernel_size` or `strides` is less than 1. ValueError: If length of `padding` tuple/list is not 1 or 2. ValueError: If length of shape of `x` is not equal to 3 or 4. ValueError: If `divisor_override` is less than or equal to 0. ValueError: If `padding` is non-zero when `pad_mode` is not 'pad'. Supported Platforms: ``Ascend`` ``GPU`` ``CPU`` Examples: >>> import mindspore as ms >>> import mindspore.nn as nn >>> import mindspore.ops as ops >>> import numpy as np >>> pool = nn.AvgPool2d(kernel_size=3, stride=1) >>> x = ms.Tensor(np.random.randint(0, 10, [1, 2, 4, 4]), ms.float32) >>> output = pool(x) >>> print(output.shape) (1, 2, 2, 2) >>> x = ops.randn(6, 6, 8, 8) >>> pool2 = nn.AvgPool2d(4, stride=1, pad_mode='pad', padding=2, divisor_override=5) >>> output2 = pool2(x) >>> print(output2.shape) (6, 6, 9, 9) """ def __init__(self, kernel_size=1, stride=1, pad_mode="valid", padding=0, ceil_mode=False, count_include_pad=True, divisor_override=None, data_format="NCHW"): """Initialize AvgPool2d.""" super(AvgPool2d, self).__init__(kernel_size, stride, pad_mode, data_format) if pad_mode.upper() == 'PAD' or padding != 0 or ceil_mode or not count_include_pad \ or divisor_override is not None: if self.format == "NHWC": raise ValueError(f"For '{self.cls_name}, the 'NHWC' format are not support when 'pad_mode' is 'pad' or " f"'padding' is not 0 or 'ceil_mode' is not False or 'count_include_pad' is not True" f"or divisor_override is not None, but got pade_mode:{pad_mode}, padding:{padding}, " f"ceil_mode:{ceil_mode}, count_include_pad:{count_include_pad}, " f"divisor_override:{divisor_override}.") self.is_expand = True if divisor_override is not None and divisor_override <= 0: raise ValueError( f"For '{self.cls_name}', the 'divisor_override' must be > 0, but got {divisor_override}.") divisor_override = 0 if divisor_override is None else divisor_override padding = _cal_padding(padding, self.cls_name, 2) if isinstance(self.kernel_size, tuple): _check_tuple_length(self.kernel_size, 'kernel_size', 2, self.cls_name) kernel_size = (1,) + self.kernel_size elif isinstance(self.kernel_size, int): kernel_size = (1, self.kernel_size, self.kernel_size) if isinstance(self.stride, tuple): _check_tuple_length(self.stride, 'stride', 2, self.cls_name) stride = (1,) + self.stride elif isinstance(self.stride, int): stride = (1, self.stride, self.stride) self.avg_pool = P.AvgPool3D(kernel_size=kernel_size, strides=stride, pad_mode=pad_mode, pad=padding, ceil_mode=ceil_mode, count_include_pad=count_include_pad, divisor_override=divisor_override) else: self.is_expand = False self.avg_pool = P.AvgPool(kernel_size=self.kernel_size, strides=self.stride, pad_mode=self.pad_mode, data_format=self.format) def construct(self, x): expand_batch = False if x.ndim == 3: x = x.unsqueeze(0) expand_batch = True if self.is_expand: x = x.unsqueeze(2) out = self.avg_pool(x) res = out.squeeze(2) else: res = self.avg_pool(x) if expand_batch: res = res.squeeze(0) return res
[文档]class AvgPool1d(_PoolNd): r""" Applies a 1D average pooling over an input Tensor which can be regarded as a composition of 1D input planes. Typically the input is of shape :math:`(N_{in}, C_{in}, L_{in})`, AvgPool1d outputs regional average in the :math:`(L_{in})`-dimension. Given `kernel_size` :math:`l_{ker}` and `stride` :math:`s_0`, the operation is as follows: .. math:: \text{output}(N_i, C_j, l) = \frac{1}{l_{ker}} \sum_{n=0}^{l_{ker}-1} \text{input}(N_i, C_j, s_0 \times l + n) Args: kernel_size (int): The size of kernel window used to take the average value, Default: 1. stride (int): The distance of kernel moving, an int number that represents the width of movement is strides, Default: 1. pad_mode (str) - Specifies the padding method of pooling, optional values are "same", "valid" or "pad", case insensitive. Default: "valid". - same: The width of the output is the same as the value after the input is divided by stride. - valid: Returns the output obtained by effective calculation without padding. The excess pixels that do not meet the calculation will be discarded. - pad: Performs padding on the input. Adds padding size of zeros to both ends of the input. If this mode is set, padding must be greater than or equal to 0. padding (Union(int, tuple[int], list[int])): Pooling padding value, only 'pad' mode can be set to non-zero. Default: 0. padding can only be an integer or a tuple/list containing a single integer, in which case padding times or padding[0] times are padded on both sides of the input. ceil_mode (bool): If True, use ceil to compute the output shape instead of floor. Default: False. count_include_pad (bool): If True, averaging calculation will include the zero-padding. Default: True. Inputs: - **x** (Tensor) - Tensor of shape :math:`(N, C_{in}, L_{in})` or :math:`(C_{in}, L_{in})`. Outputs: Tensor of shape :math:`(N, C_{out}, L_{out})` or :math:`(C_{out}, L_{out})`. If `pad_mode` is in `pad` mode, the output shape calculation formula is as follows: .. math:: L_{out} = \left\lfloor \frac{L_{in} + 2 \times \text{padding} - \text{kernel_size}}{\text{stride}} + 1\right\rfloor Raises: TypeError: If `kernel_size` or `stride` is not an int. ValueError: If `pad_mode` is not 'valid' ,'same' or 'pad' with not case sensitive. ValueError: If `kernel_size` or `strides` is less than 1. ValueError: If length of `padding` tuple/list is not 1. ValueError: If length of shape of `x` is not equal to 2 or 3. ValueError: If `padding` is non-zero when `pad_mode` is not 'pad'. Supported Platforms: ``Ascend`` ``GPU`` ``CPU`` Examples: >>> import mindspore as ms >>> import mindspore.nn as nn >>> import mindspore.ops as ops >>> import numpy as np >>> pool = nn.AvgPool1d(kernel_size=6, stride=1) >>> x = ms.Tensor(np.random.randint(0, 10, [1, 3, 6]), ms.float32) >>> output = pool(x) >>> result = output.shape >>> print(result) (1, 3, 1) >>> pool2 = nn.AvgPool1d(4, stride=1, ceil_mode=True, pad_mode='pad', padding=2) >>> x1 = ops.randn(6, 6, 8) >>> output = pool2(x1) >>> print(output.shape) (6, 6, 9) """ def __init__(self, kernel_size=1, stride=1, pad_mode="valid", padding=0, ceil_mode=False, count_include_pad=True): """Initialize AvgPool1d.""" super(AvgPool1d, self).__init__(kernel_size, stride, pad_mode) validator.check_int(self.kernel_size, 1, validator.GE, "kernel_size", self.cls_name) validator.check_int(self.stride, 1, validator.GE, "stride", self.cls_name) if pad_mode.upper() == 'PAD' or padding != 0 or ceil_mode or not count_include_pad: padding = _cal_padding(padding, self.cls_name, 1) self.is_expand_3d = True kernel_size = (1, 1, self.kernel_size) stride = (1, 1, self.stride) self.avg_pool = P.AvgPool3D(kernel_size=kernel_size, strides=stride, pad_mode=pad_mode, pad=padding, ceil_mode=ceil_mode, count_include_pad=count_include_pad) else: self.is_expand_3d = False self.kernel_size = (1, self.kernel_size) self.stride = (1, self.stride) self.avg_pool = P.AvgPool(kernel_size=self.kernel_size, strides=self.stride, pad_mode=self.pad_mode) self.shape = F.shape self.reduce_mean = P.ReduceMean(keep_dims=True) self.slice = P.Slice() self.expand = P.ExpandDims() self.squeeze = P.Squeeze(2) def construct(self, x): expand_batch = False if x.ndim == 2: x = x.unsqueeze(0) expand_batch = True if self.is_expand_3d: x = x.unsqueeze(2).unsqueeze(3) x = self.avg_pool(x) x = x.squeeze(3).squeeze(2) else: _shape_check(self.shape(x), self.cls_name) batch, channel, width = self.shape(x) if width == self.kernel_size[1]: x = self.reduce_mean(x, 2) elif width - self.kernel_size[1] < self.stride[1]: x = self.slice(x, (0, 0, 0), (batch, channel, self.kernel_size[1])) x = self.reduce_mean(x, 2) else: x = self.expand(x, 2) x = self.avg_pool(x) x = self.squeeze(x) if expand_batch: x = x.squeeze(0) return x
@_primexpr def _adaptive_shape_check(in_shape, output_size, prim_name): """Check shape.""" msg_prefix = "For {}, the".format(prim_name) if len(in_shape) != 3: raise ValueError("{} input must has 3 dim, but got {}.".format(msg_prefix, len(in_shape))) if in_shape[2] < output_size: raise ValueError("{} input's last dimension must be greater or equal to " "output size {}, but got {}.".format(msg_prefix, output_size, in_shape[2])) if in_shape[2] % output_size != 0: raise ValueError("{} input's last dimension must be divisible by " "output size {}, but got {}.".format(msg_prefix, output_size, in_shape[2])) @constexpr def _adaptive_dtype_check(x_dtype, prim_name): """Check dtype.""" if x_dtype not in [mstype.float16, mstype.float32]: raise TypeError("For {}, the x_dtype must be float16 or float32, " "but got {}.".format(prim_name, x_dtype))
[文档]class AdaptiveAvgPool1d(Cell): r""" Applies a 1D adaptive average pooling over an input Tensor which can be regarded as a composition of 1D input planes. Typically, the input is of shape :math:`(N_{in}, C_{in}, L_{in})`, AdaptiveAvgPool1d outputs regional average in the :math:`L_{in}`-dimension. The output is of shape :math:`(N_{in}, C_{in}, L_{out})`, where :math:`L_{out}` is defined by `output_size`. Note: :math:`L_{in}` must be divisible by `output_size`. Args: output_size (int): the target output size :math:`L_{out}`. Inputs: - **input** (Tensor) - Tensor of shape :math:`(N, C_{in}, L_{in})`, with float16 or float32 data type. Outputs: Tensor of shape :math:`(N, C_{in}, L_{out})`, has the same type as `input`. Raises: TypeError: If `output_size` is not an int. TypeError: If `input` is neither float16 nor float32. ValueError: If `output_size` is less than 1. ValueError: If length of shape of `input` is not equal to 3. ValueError: If the last dimension of `input` is smaller than `output_size`. ValueError: If the last dimension of `input` is not divisible by `output_size`. Supported Platforms: ``Ascend`` ``GPU`` ``CPU`` Examples: >>> import mindspore >>> from mindspore import Tensor, nn >>> import numpy as np >>> pool = nn.AdaptiveAvgPool1d(output_size=2) >>> input = Tensor(np.random.randint(0, 10, [1, 3, 6]), mindspore.float32) >>> output = pool(input) >>> result = output.shape >>> print(result) (1, 3, 2) """ def __init__(self, output_size): """Initialize AdaptiveAvgPool1d.""" super(AdaptiveAvgPool1d, self).__init__() validator.check_value_type('output_size', output_size, [int], self.cls_name) validator.check_int(output_size, 1, validator.GE, "output_size", self.cls_name) self.shape = F.shape self.expand = P.ExpandDims() self.squeeze = P.Squeeze(2) self.output_size = output_size self.dtype = P.DType() def construct(self, input): _adaptive_shape_check(self.shape(input), self.output_size, self.cls_name) _adaptive_dtype_check(self.dtype(input), self.cls_name) _, _, width = self.shape(input) stride = width // self.output_size kernel_size = width - (self.output_size - 1) * stride stride = (1, width // self.output_size) kernel_size = (1, kernel_size) input = self.expand(input, 2) avg_pool = P.AvgPool(kernel_size=kernel_size, strides=stride) input = avg_pool(input) input = self.squeeze(input) return input
[文档]class AdaptiveAvgPool2d(Cell): r""" This operator applies a 2D adaptive average pooling to an input signal composed of multiple input planes. That is, for any input size, the size of the specified output is H x W. The number of output features is equal to the number of input features. The input and output data format can be "NCHW" and "CHW". N is the batch size, C is the number of channels, H is the feature height, and W is the feature width. .. math:: \begin{align} h_{start} &= floor(i * H_{in} / H_{out})\\ h_{end} &= ceil((i + 1) * H_{in} / H_{out})\\ w_{start} &= floor(j * W_{in} / W_{out})\\ w_{end} &= ceil((j + 1) * W_{in} / W_{out})\\ Output(i,j) &= \frac{\sum Input[h_{start}:h_{end}, w_{start}:w_{end}]}{(h_{end}- h_{start}) * (w_{end}- w_{start})} \end{align} Args: output_size (Union[int, tuple]): The target output size is H x W. `output_size` can be a tuple consisted of int type H and W, or a single H for H x H, or None. If it is None, it means the output size is the same as the input size. Inputs: - **input** (Tensor) - The input of AdaptiveAvgPool2d, which is a 3D or 4D tensor, with float16, float32 or float64 data type. Outputs: Tensor of shape :math:`(N, C_{out}, H_{out}, W_{out})`. Raises: ValueError: If `output_size` is a tuple and the length of `output_size` is not 2. TypeError: If `input` is not a Tensor. TypeError: If dtype of `input` is not float16, float32 or float64. ValueError: If the dimension of `input` is less than or equal to the dimension of `output_size`. Supported Platforms: ``GPU`` Examples: >>> pool = nn.AdaptiveAvgPool2d(2) >>> input_x = Tensor(np.array([[[1.0, 2.0, 3.0], [4.0, 5.0, 6.0], [7.0, 8.0, 9.0]], ... [[1.0, 2.0, 3.0], [4.0, 5.0, 6.0], [7.0, 8.0, 9.0]], ... [[1.0, 2.0, 3.0], [4.0, 5.0, 6.0], [7.0, 8.0, 9.0]]]), mindspore.float32) >>> output = pool(input_x) >>> result = output.shape >>> print(result) (3, 2, 2) """ def __init__(self, output_size): """Initialize AdaptiveAvgPool2d.""" super(AdaptiveAvgPool2d, self).__init__() self.adaptive_avgpool2d = P.AdaptiveAvgPool2D(output_size) def construct(self, input): return self.adaptive_avgpool2d(input)
[文档]class AdaptiveAvgPool3d(Cell): r""" This operator applies a 3D adaptive average pooling to an input signal composed of multiple input planes. That is, for any input size, the size of the specified output is :math:`(D, H, W)`. The number of output features is equal to the number of input planes. Suppose the last 3 dimension size of input is :math:`(inD, inH, inW)`, then the last 3 dimension size of output is :math:`(outD, outH, outW)`. .. math:: \begin{array}{ll} \\ \forall \quad od \in [0,outD-1], oh \in [0,outH-1], ow \in [0,outW-1]\\ output[od,oh,ow] = \\ \qquad mean(input[istartD:iendD+1,istartH:iendH+1,istartW:iendW+1])\\ where,\\ \qquad istartD= \left\lceil \frac{od * inD}{outD} \right\rceil \\ \qquad iendD=\left\lfloor \frac{(od+1)* inD}{outD} \right\rfloor \\ \qquad istartH=\left\lceil \frac{oh * inH}{outH} \right\rceil \\ \qquad iendH=\left\lfloor \frac{(oh+1) * inH}{outH} \right\rfloor \\ \qquad istartW=\left\lceil \frac{ow * inW}{outW} \right\rceil \\ \qquad iendW=\left\lfloor \frac{(ow+1) * inW}{outW} \right\rfloor \end{array} Args: output_size (Union[int, tuple]): The target output size. `output_size` can be a tuple :math:`(D, H, W)`, or an int D for :math:`(D, D, D)`. :math:`D`, :math:`H` and :math:`W` can be int or None which means the output size is the same as that of the input. Inputs: - **input** (Tensor) - The input of AdaptiveAvgPool3d, which is a 5D or 4D Tensor, with float16, float32 or float64 data type. Outputs: Tensor, with the same type as the `input`. Raises: TypeError: If `input` is not a Tensor. TypeError: If dtype of `input` is not float16, float32 or float64. ValueError: If the dimension of `input` is not 4D or 5D. ValueError: If `output_size` value is not positive. Supported Platforms: ``Ascend`` ``GPU`` ``CPU`` Examples: >>> # case 1: output_size=(3, 3, 4) >>> output_size=(3, 3, 4) >>> input_x_val = np.random.randn(4, 3, 5, 6, 7) >>> input_x = Tensor(input_x_val, mindspore.float32) >>> net = nn.AdaptiveAvgPool3d(output_size) >>> output = net(input_x) >>> print(output.shape) (4, 3, 3, 3, 4) >>> # case 2: output_size=4 >>> output_size=5 >>> input_x_val = np.random.randn(2, 3, 8, 6, 12) >>> input_x = Tensor(input_x_val, mindspore.float32) >>> net = nn.AdaptiveAvgPool3d(output_size) >>> output = net(input_x) >>> print(output.shape) (2, 3, 5, 5, 5) >>> # case 3: output_size=(None, 4, 5) >>> output_size=(None, 4, 5) >>> input_x_val = np.random.randn(4, 1, 9, 10, 8) >>> input_x = Tensor(input_x_val, mindspore.float32) >>> net = nn.AdaptiveAvgPool3d(output_size) >>> output = net(input_x) >>> print(output.shape) (4, 1, 9, 4, 5) """ def __init__(self, output_size): """Initialize AdaptiveAvgPool3d.""" super(AdaptiveAvgPool3d, self).__init__() self.adaptive_avg_pool3d = AdaptiveAvgPool3D(output_size) def construct(self, input): return self.adaptive_avg_pool3d(input)
[文档]class AdaptiveMaxPool1d(Cell): r""" Applies a 1D adaptive maximum pooling over an input Tensor which can be regarded as a composition of 1D input planes. Typically, the input is of shape :math:`(N_{in}, C_{in}, L_{in})`, AdaptiveMaxPool1d outputs regional maximum in the :math:`L_{in}`-dimension. The output is of shape :math:`(N_{in}, C_{in}, L_{out})`, where :math:`L_{out}` is defined by `output_size`. Note: :math:`L_{in}` must be divisible by `output_size`. Args: output_size (int): the target output size :math:`L_{out}`. Inputs: - **x** (Tensor) - Tensor of shape :math:`(N, C_{in}, L_{in})`, with float16 or float32 data type. Outputs: Tensor of shape :math:`(N, C_{in}, L_{out})`, has the same type as `x`. Raises: TypeError: If `x` is neither float16 nor float32. TypeError: If `output_size` is not an int. ValueError: If `output_size` is less than 1. ValueError: If the last dimension of `x` is smaller than `output_size`. ValueError: If the last dimension of `x` is not divisible by `output_size`. ValueError: If length of shape of `x` is not equal to 3. Supported Platforms: ``Ascend`` ``GPU`` ``CPU`` Examples: >>> import mindspore >>> from mindspore import Tensor, nn >>> import numpy as np >>> pool = nn.AdaptiveMaxPool1d(output_size=3) >>> x = Tensor(np.random.randint(0, 10, [1, 3, 6]), mindspore.float32) >>> output = pool(x) >>> result = output.shape >>> print(result) (1, 3, 3) """ def __init__(self, output_size): """Initialize AdaptiveMaxPool1d.""" super(AdaptiveMaxPool1d, self).__init__() validator.check_int(output_size, 1, validator.GE, "output_size", self.cls_name) validator.check_value_type('output_size', output_size, [int], self.cls_name) self.expand = P.ExpandDims() self.squeeze = P.Squeeze(2) self.output_size = output_size self.shape = F.shape self.dtype = P.DType() def construct(self, x): _adaptive_shape_check(self.shape(x), self.output_size, self.cls_name) _adaptive_dtype_check(self.dtype(x), self.cls_name) _, _, width = self.shape(x) stride = width // self.output_size kernel_size = width - (self.output_size - 1) * stride stride = (1, width // self.output_size) kernel_size = (1, kernel_size) max_pool = P.MaxPool(kernel_size=kernel_size, strides=stride) x = self.expand(x, 2) x = max_pool(x) x = self.squeeze(x) return x
[文档]class AdaptiveMaxPool2d(Cell): r""" This operator applies a 2D adaptive max pooling to an input signal composed of multiple input planes. That is, for any input size, the size of the specified output is H x W. The number of output features is equal to the number of input planes. The input and output data format can be "NCHW" and "CHW". N is the batch size, C is the number of channels, H is the feature height, and W is the feature width. For max adaptive pool2d: .. math:: \begin{align} h_{start} &= floor(i * H_{in} / H_{out})\\ h_{end} &= ceil((i + 1) * H_{in} / H_{out})\\ w_{start} &= floor(j * W_{in} / W_{out})\\ w_{end} &= ceil((j + 1) * W_{in} / W_{out})\\ Output(i,j) &= {\max Input[h_{start}:h_{end}, w_{start}:w_{end}]} \end{align} Note: Ascend platform only supports float16 type for input. Args: output_size (Union[int, tuple]): The target output size. `output_size` can be a tuple :math:`(H, W)`, or an int H for :math:`(H, H)`. :math:`H` and :math:`W` can be int or None. If it is None, it means the output size is the same as the input size. return_indices (bool): If `return_indices` is True, the indices of max value would be output. Default: False. Inputs: - **input** (Tensor) - The input of AdaptiveMaxPool2d, which is a 3D or 4D tensor, with float16, float32 or float64 data type. Outputs: Tensor, with the same type as the `input`. Shape of the output is `input_shape[:len(input_shape) - len(out_shape)] + out_shape`. Raises: TypeError: If `output_size` is not int or tuple. TypeError: If `input` is not a tensor. TypeError: If `return_indices` is not a bool. TypeError: If dtype of `input` is not float16, float32 or float64. ValueError: If `output_size` is a tuple and the length of `output_size` is not 2. ValueError: If the dimension of `input` is not NCHW or CHW. Supported Platforms: ``Ascend`` ``GPU`` ``CPU`` Examples: >>> # case 1: output_size=(None, 2) >>> input = Tensor(np.array([[[[1.0, 2.0, 3.0], [4.0, 5.0, 6.0], [7.0, 8.0, 9.0]], ... [[1.0, 2.0, 3.0], [4.0, 5.0, 6.0], [7.0, 8.0, 9.0]], ... [[1.0, 2.0, 3.0], [4.0, 5.0, 6.0], [7.0, 8.0, 9.0]]]]), mindspore.float32) >>> adaptive_max_pool_2d = nn.AdaptiveMaxPool2d((None, 2)) >>> output = adaptive_max_pool_2d(input) >>> print(output) [[[[2. 3.] [5. 6.] [8. 9.]] [[2. 3.] [5. 6.] [8. 9.]] [[2. 3.] [5. 6.] [8. 9.]]]] >>> # case 2: output_size=2 >>> adaptive_max_pool_2d = nn.AdaptiveMaxPool2d(2) >>> output = adaptive_max_pool_2d(input) >>> print(output) [[[[5. 6.] [8. 9.]] [[5. 6.] [8. 9.]] [[5. 6.] [8. 9.]]]] >>> # case 3: output_size=(1, 2) >>> adaptive_max_pool_2d = nn.AdaptiveMaxPool2d((1, 2)) >>> output = adaptive_max_pool_2d(input) >>> print(output) [[[[8. 9.]] [[8. 9.]] [[8. 9.]]]] """ def __init__(self, output_size, return_indices=False): """Initialize AdaptiveMaxPool2d.""" super(AdaptiveMaxPool2d, self).__init__() validator.check_value_type('return_indices', return_indices, [bool], self.cls_name) self.adaptive_max_pool2d = AdaptiveMaxPool2D(output_size) self.return_indices = return_indices def construct(self, input): output = self.adaptive_max_pool2d(input) if self.return_indices: return output return output[0]
[文档]class AdaptiveMaxPool3d(Cell): r""" Calculates the 3D adaptive max pooling for an input Tensor. That is, for any input size, the size of the specified output is :math:`(D, H, W)`. Args: output_size (Union[int, tuple]): The specified output size, which is a positive integer that represents depth, height and width, or a tuple of three positive integers that represent depth, height and width respectively. If it is None, the output size and input size of the corresponding dimension are the same. return_indices (bool, optional): If `return_indices` is True, the indices of max value would be output. Otherwise, the indices will not be returned. Default: False. Inputs: - **input** (Tensor) - Tensor, has shape of :math:`(C, D, H, W)` or :math:`(N, C, D, H, W)`. Outputs: - **y** (Tensor) - Tensor, has the same number of dims and data type as the `input` . - **argmax** (Tensor) - Tensor, the indices of the maximum values along with the outputs, has the same shape as `y` and a dtype of int32. Return this only when `return_indices` is True. Raises: TypeError: If `input` is not a Tensor. ValueError: If the dimensions number of `input` is not 4 or 5. TypeError: If dtype of `input` is not int, uint or float. ValueError: If `output_size` is neither an int nor a tuple with shape (3,). Supported Platforms: ``GPU`` ``CPU`` Examples: >>> input = Tensor(np.arange(0,36).reshape((1, 3, 3, 4)).astype(np.float32)) >>> output_size = (1, 1, 2) >>> net = nn.AdaptiveMaxPool3d(output_size, True) >>> output = net(input) >>> print(output[0].asnumpy()) [[[[33. 35.]]]] >>> print(output[1].asnumpy()) [[[[33 35]]]] """ def __init__(self, output_size, return_indices=False): """Initialize AdaptiveMaxPool3d.""" super(AdaptiveMaxPool3d, self).__init__() self.output_size = Tensor(output_size, dtype=mstype.int32) self.return_indices = return_indices self.adaptive_max_pool3d = AdaptiveMaxPool3D() def construct(self, input): output = self.adaptive_max_pool3d(input, self.output_size) if self.return_indices: return output return output[0]
class FractionalMaxPool2d(Cell): r""" Applies the 2D FractionalMaxPool operatin over input. The output Tensor shape can be determined by either `output_size` or `output_ratio`, and the step size is determined by `_random_samples`. `output_size` will take effect when `output_size` and `output_ratio` are set at the same time. And `output_size` and `output_ratio` can not be ``None`` at the same time. Refer to the paper `Fractional MaxPooling by Ben Graham <https://arxiv.org/abs/1412.6071>`_ for more details. Args: kernel_size (Union[int, tuple[int]]): The size of kernel used to take the maximum value, is an int number that represents height and width of the kernel, or a tuple of two int numbers that represent height and width respectively. The value must be a positive integer. output_size (Union[int, tuple[int]], optional): The Shape of the target `output_size`, is a positive int that represents height and width, or a tuple of two positive integers that represent height and width respectively. The value must be a positive integer. If None, the shape of the target will be determined by `output_ratio`. Default: None. output_ratio (Union[float, tuple[float]], optional): The ratio of target output shape to input shape. Specifying the size of the output tensor by using a ratio of the input size. Data type : float16, float32, float64, and value is between (0, 1). If None, the shape of the target will be determined by `output_size`. Default: None. return_indices (bool, optional): Whether to return the indices of max value. Default: False. _random_samples (Tensor, optional): The random step of FractionalMaxPool2d, which is a 3D tensor. Tensor of data type: float16, float32, double, and value is between [0, 1). Supported shape :math:`(N, C, 2)` or :math:`(1, C, 2)`. Default: ``None``, the values of `_random_samples` will be randomly distributed using uniform distribution over an interval [0,1). Inputs: - **input** (Tensor) - Tensor of shape :math:`(N, C, H_{in}, W_{in})` or :math:`(C, H_{in}, W_{in})`, with float16, float32, float64, int32, int64 data type. Outputs: - **y** (Tensor) - Has the same type as the `input`. Has the shape :math:`(N, C, H_{out}, W_{out})` or :math:`(C, H_{out}, W_{out})` , where :math:`(H_{out}, W_{out})` = `output_size` or :math:`(H_{out}, W_{out})` = `output_ratio` * :math:`(H_{in}, W_{in})`. - **argmax** (Tensor) - The indices along with the outputs, which is a Tensor, with the same shape as the `y` and int64 data type. It will be returned only when `return_indices` is True. Raises: TypeError: If data type of `input` is not one of the following: float16, float32, float64, int32, int64. TypeError: If data type of `_random_samples` is not one of the following: float16, float32, float64. ValueError: If `kernel_size` is not a number and `kernel_size` is not a tuple of length 2. ValueError: If `output_size` is not a number and `output_size` is not a tuple of length 2. ValueError: If the sum of `kernel_size` , `output_size` and -1 is larger than the corresponding dimension of `input`. ValueError: If the dimension of `_random_samples` is not 3. ValueError: if `output_size` and `output_ratio` are None at the same time. ValueError: If the first dimension size of `input` and `_random_samples` is not equal. ValueError: If the second dimension size of `input` and `_random_samples` is not equal. ValueError: If the third dimension size of `_random_samples` is not 2. Supported Platforms: ``CPU`` Examples: >>> # the kernel_size is an int number and the output_size is a tuple. >>> import numpy as np >>> from mindspore import nn >>> from mindspore import Tensor >>> import mindspore.common.dtype as mstype >>> input = Tensor(np.array([0.3220, 0.9545, 0.7879, 0.0975, 0.3698, ... 0.5135, 0.5740, 0.3435, 0.1895, 0.8764, ... 0.9581, 0.4760, 0.9014, 0.8522, 0.3664, ... 0.4980, 0.9673, 0.9879, 0.6988, 0.9022, ... 0.9304, 0.1558, 0.0153, 0.1559, 0.9852]).reshape([1, 1, 5, 5]), mstype.float32) >>> _random_samples = Tensor(np.array([[[0.8, 0.8]]]), mstype.float32) >>> net = nn.FractionalMaxPool2d(kernel_size=2, output_size=(2, 2), _random_samples=_random_samples, ... return_indices=True) >>> y, argmax = net(input) >>> y [[[[0.9545 0.8764] [0.9673 0.9852]]]] >>> argmax [[[[ 1 9] [16 24]]]] >>> net = nn.FractionalMaxPool2d(kernel_size=2, output_ratio=(0.5, 0.5), _random_samples=_random_samples, ... return_indices=True) >>> y, argmax = net(input) >>> print(y) [[[[0.9545 0.8764] [0.9673 0.9852]]]] >>> print(argmax) [[[[ 1 9] [16 24]]]] """ def __init__(self, kernel_size, output_size=None, output_ratio=None, return_indices=False, _random_samples=None): """Initialize FractionalMaxPool2d.""" super(FractionalMaxPool2d, self).__init__() self.kernel_size = kernel_size self.output_size = output_size self.output_ratio = output_ratio self.return_indices = return_indices self._random_samples = _random_samples def construct(self, input): return ops.fractional_max_pool2d(input, self.kernel_size, self.output_size, self.output_ratio, self.return_indices, self._random_samples)
[文档]class FractionalMaxPool3d(Cell): r""" Applies the 3D FractionalMaxPool operatin over `input`. The output Tensor shape can be determined by either `output_size` or `output_ratio`, and the step size is determined by `_random_samples`. `output_size` will take effect when `output_size` and `output_ratio` are set at the same time. And `output_size` and `output_ratio` can not be ``None`` at the same time. Refer to the paper `Fractional MaxPooling by Ben Graham <https://arxiv.org/abs/1412.6071>`_ for more details. The input and output data format can be "NCDHW". N is the batch size, C is the number of channels, D the feature depth, H is the feature height, and W is the feature width. Args: kernel_size (Union[int, tuple[int]]): The size of kernel used to take the maximum value, is a positive int that represents depth, height and width of the kernel, or a tuple of three positive integers that represent depth, height and width respectively. output_size (Union[int, tuple[int]], optional): The shape of the target `output_size`, is an int number that represents depth, height and width, or a tuple of three positive integers that represents depth, height and width respectively. If None, the shape of the target will be determined by `output_ratio`. Default: None. output_ratio (Union[float, tuple[float]], optional): The ratio of target output shape to input shape. Specifying the size of the output tensor by using a ratio of the input size. Data type : float16, float32, float64, and value is between (0, 1). If None, the shape of the target will be determined by `output_size`.Default: None. return_indices (bool, optional): Whether to return the indices of max value. Default: False. _random_samples (Tensor, optional): The random step of FractionalMaxPool3d, which is a 3D tensor. Tensor of data type: float16, float32, double, and value is between [0, 1). Supported shape :math:`(N, C, 3)` or :math:`(1, C, 3)` . Default: ``None``, the values of `_random_samples` will be randomly distributed using uniform distribution over an interval [0,1). Inputs: - **input** (Tensor) - The input of FractionalMaxPool3d, which is a 4D or 5D tensor. Tensor of data type : float16, float32, float64. Supported shape :math:`(N, C, D_{in}, H_{in}, W_{in})` or :math:`(C, D_{in}, H_{in}, W_{in})`. Outputs: - **y** (Tensor) - A tensor, the output of FractionalMaxPool3d. Has the same data type with `input`. Has the shape :math:`(N, C, D_{out}, H_{out}, W_{out})` or :math:`(C, D_{out}, H_{out}, W_{out})` , where :math:`(D_{out}, H_{out}, W_{out})` = `output_size` or :math:`(D_{out}, H_{out}, W_{out})` = `output_ratio` * :math:`(D_{in}, H_{in}, W_{in})` . - **argmax** (Tensor) - The indices along with the outputs, which is a Tensor, with the same shape as the `y` and int32 data type. It will output only when `return_indices` is True. Raises: TypeError: If `input` is not a 4D or 5D tensor. TypeError: If `_random_samples` is not a 3D tensor. TypeError: If data type of `imput_x` is not float16, float32, float64. TypeError: If dtype of `_random_samples` is not float16, float32, float64. TypeError: If dtype of `argmax` is not int32, int64. TypeError: if _random_samples to have the different dtypes as input. ValueError: If `output_size` is a tuple and if `output_size` length is not 3. ValueError: If `kernel_size` is a tuple and if `kernel_size` length is not 3. ValueError: If numbers in `output_size` or `kernel_size` is not positive. ValueError: if `output_size` and `output_ratio` are None at the same time. ValueError: If the first dimension size of `input` and `_random_samples` is not equal. ValueError: If the second dimension size of `input` and `_random_samples` is not equal. ValueError: If the third dimension size of `_random_samples` is not 3. Supported Platforms: ``GPU`` ``CPU`` Examples: >>> import numpy as np >>> from mindspore import nn >>> from mindspore import Tensor >>> import mindspore.common.dtype as mstype >>> x = Tensor(np.array([1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16]) ... .reshape([1, 1, 2, 2, 4]), mstype.float32) >>> _random_samples = Tensor(np.array([0.7, 0.7, 0.7]).reshape([1, 1, 3]), mstype.float32) >>> net = nn.FractionalMaxPool3d(kernel_size=(1, 1, 1), output_size=(1, 1, 3), ... _random_samples=_random_samples, return_indices=True) >>> output, argmax = net(x) >>> print(output) [[[[[13. 14. 16.]]]]] >>> print(argmax) [[[[[12 13 15]]]]] >>> net = nn.FractionalMaxPool3d(kernel_size=(1, 1, 1), output_ratio=(0.5, 0.5, 0.5), ... _random_samples=_random_samples, return_indices=True) >>> output, argmax = net(x) >>> print(output) [[[[[13. 16.]]]]] >>> print(argmax) [[[[[12 15]]]]] """ def __init__(self, kernel_size, output_size=None, output_ratio=None, return_indices=False, _random_samples=None): """Initialize FractionalMaxPool3d.""" super(FractionalMaxPool3d, self).__init__() self.kernel_size = kernel_size self.output_size = output_size self.output_ratio = output_ratio self.return_indices = return_indices self._random_samples = _random_samples def construct(self, input): return ops.fractional_max_pool3d(input, self.kernel_size, self.output_size, self.output_ratio, self.return_indices, self._random_samples)
[文档]class MaxUnpool1d(Cell): r""" Computes the inverse of :class:`mindspore.nn.MaxPool1d`. MaxUnpool1d keeps the maximal value and set all position of non-maximal values to zero. Typically the input is of shape :math:`(N, C, H_{in})` or :math:`(C, H_{in})`, and the output is of shape :math:`(N, C, H_{out})` or :math:`(C, H_{out})`. The operation is as follows. .. math:: \begin{array}{ll} \\ H_{out} = (H{in} - 1) \times stride[0] - 2 \times padding[0] + kernel\_size[0] \\ \end{array} Args: kernel_size (Union[int, tuple[int]]): The size of kernel used to take the maximum value. stride (Union[int, tuple[int]]): The distance of kernel moving, If stride is None, then stride equal to kernel_size. Default: None. padding (Union[int, tuple[int]]): The pad value to be filled. Default: 0. Inputs: - **x** (Tensor) - The input Tensor to invert. Tensor of shape :math:`(N, C, H_{in})` or :math:`(C, H_{in})`. - **indices** (Tensor) - Max values' index represented by the indices. Tensor of shape must be same with input 'x'. Values of indices must belong to :math:`[0, H_{in} - 1]`. Data type must be in int32 or int64. - **output_size** (tuple[int], optional) - The output size. Default: None. If output_size == (), then the shape of output computed by kernel_size, stride and padding. If output_size != (), then output_size must be :math:`(N, C, H)` , :math:`(C, H)` or :math:`(H)` and output_size must belong to :math:`[(N, C, H_{out} - stride[0]), (N, C, H_{out} + stride[0])]`. Outputs: Tensor, with shape :math:`(N, C, H_{out})` or :math:`(C, H_{out})`, with the same data type with `x`. Raises: TypeError: If data type of `x` or `indices` is not supported. TypeError: If `kernel_size`, `stride` or `padding` is neither an int nor a tuple. ValueError: If numbers in `stride`, `padding` (also support 0 and (0)) or `kernel_size` is not positive. ValueError: If the shapes of `x` and `indices` are not equal. ValueError: If `x` whose length is not 2 or 3. ValueError: If type of `output_size` is not tuple. ValueError: If `output_size` whose length is not 0, 2 or 3. ValueError: If `output_size` is not close to output size computed by attr `kernel_size`, `stride`, `padding`. Supported Platforms: ``GPU`` ``CPU`` Examples: >>> x = Tensor(np.array([[2, 4, 6, 8]]).astype(np.float32)) >>> indices = Tensor(np.array([[1, 3, 5, 7]]).astype(np.int64)) >>> maxunpool1d = nn.MaxUnpool1d(kernel_size =2, stride=2, padding=0) >>> output = maxunpool1d(x, indices) >>> print(output.asnumpy()) [[0. 2. 0. 4. 0. 6. 0. 8.]] """ def __init__(self, kernel_size, stride=None, padding=0): """Initialize MaxUnpool1d.""" super(MaxUnpool1d, self).__init__() if stride is None: stride = kernel_size self.kernel_size = kernel_size self.stride = stride self.padding = padding def construct(self, x, indices, output_size=None): if output_size is None: output_size = () else: if not isinstance(output_size, tuple): raise ValueError(f"For MaxUnpool1d, output_size must be tuple, but type {type(output_size)}.") out = ops.max_unpool1d(x, indices, self.kernel_size, stride=self.stride, padding=self.padding, output_size=output_size) return out
[文档]class MaxUnpool2d(Cell): r""" Computes the inverse of :class:`mindspore.nn.MaxPool2d`. MaxUnpool2d keeps the maximal value and set all position of non-maximal values to zero. Typically the input is of shape :math:`(N, C, H_{in}, W_{in})` or :math:`(C, H_{in}, W_{in})`, and the output is of shape :math:`(N, C, H_{out}, W_{out})` or :math:`(C, H_{out}, W_{out})`. The operation is as follows. .. math:: \begin{array}{ll} \\ H_{out} = (H{in} - 1) \times stride[0] - 2 \times padding[0] + kernel\_size[0] \\ W_{out} = (W{in} - 1) \times stride[1] - 2 \times padding[1] + kernel\_size[1] \\ \end{array} Args: kernel_size (Union[int, tuple[int]]): The size of kernel used to take the maximum value, an int number that represents height and width of the kernel, or a tuple of two int numbers that represent height and width respectively. stride (Union[int, tuple[int]]): The distance of kernel moving, an int number that represents the height and width of movement are both stride, or a tuple of two int numbers that represent height and width of movement respectively. If stride is None, then stride equal to kernel_size. Default: None. padding (Union[int, tuple[int]]): The pad value to be filled. Default: 0. If `padding` is an integer, the paddings of height and width are the same, equal to padding. If `padding` is a tuple of two integers, the padding of height and width equal to padding[0] and padding[1] correspondingly. Inputs: - **x** (Tensor) - The input Tensor to invert. Tensor of shape :math:`(N, C, H_{in}, W_{in})` or :math:`(C, H_{in}, W_{in})`. - **indices** (Tensor) - Max values' index represented by the indices. Tensor of shape must be same with input 'x'. Values of indices must belong to :math:`[0, H_{in} \times W_{in} - 1]`. Data type must be in int32 or int64. - **output_size** (tuple[int], optional) - The output size. Default: None. If output_size == (), then the shape of output computed by kernel_size, stride and padding. If output_size != (), then output_size must be :math:`(N, C, H, W)`, :math:`(C, H, W)` or :math:`(H, W)` and output_size must belong to :math:`[(N, C, H_{out} - stride[0], W_{out} - stride[1]), (N, C, H_{out} + stride[0], W_{out} + stride[1])]`. Outputs: Tensor, with shape :math:`(N, C, H_{out}, W_{out})` or :math:`(C, H_{out}, W_{out})`, with the same data type with `x`. Raises: TypeError: If data type of `x` or `indices` is not supported. TypeError: If `kernel_size`, `stride` or `padding` is neither an int nor a tuple. ValueError: If numbers in `stride`, `padding` (also support 0 and (0, 0)) or `kernel_size` is not positive. ValueError: If the shape of `x` and `indices` are not equal. ValueError: If `kernel_size`, `stride` or `padding` is a tuple whose length is not equal to 2. ValueError: If `x` whose length is not 3 or 4. ValueError: If `output_size` whose type is not tuple. ValueError: If `output_size` whose length is not 0, 3 or 4. ValueError: If `output_size` is not close to output size computed by attr `kernel_size`, `stride`, `padding`. Supported Platforms: ``GPU`` ``CPU`` Examples: >>> x = Tensor(np.array([[[[0, 1], [8, 9]]]]).astype(np.float32)) >>> indices = Tensor(np.array([[[[0, 1], [2, 3]]]]).astype(np.int64)) >>> maxunpool2d = nn.MaxUnpool2d(kernel_size=1, stride=1, padding=0) >>> output = maxunpool2d(x, indices) >>> print(output.asnumpy()) [[[[0. 1.] [8. 9.]]]] """ def __init__(self, kernel_size, stride=None, padding=0): """Initialize MaxUnpool2d.""" super(MaxUnpool2d, self).__init__() if stride is None: stride = kernel_size self.kernel_size = kernel_size self.stride = stride self.padding = padding def construct(self, x, indices, output_size=None): if output_size is None: output_size = () else: if not isinstance(output_size, tuple): raise ValueError(f"For MaxUnpool2d, output_size must be tuple, but type {type(output_size)}.") out = ops.max_unpool2d(x, indices, self.kernel_size, stride=self.stride, padding=self.padding, output_size=output_size) return out
[文档]class MaxUnpool3d(Cell): r""" Computes the inverse of :class:`mindspore.nn.MaxPool3d`. MaxUnpool3d keeps the maximal value and set all position of non-maximal values to zero. Typically the input is of shape :math:`(N, C, D_{in}, H_{in}, W_{in})` or :math:`(C, D_{in}, H_{in}, W_{in})`, and the output is of shape :math:`(N, C, D_{out}, H_{out}, W_{out})` or :math:`(C, D_{out}, H_{out}, W_{out})`. The operation is as follows. .. math:: \begin{array}{ll} \\ D_{out} = (D{in} - 1) \times stride[0] - 2 \times padding[0] + kernel\_size[0] \\ H_{out} = (H{in} - 1) \times stride[1] - 2 \times padding[1] + kernel\_size[1] \\ W_{out} = (W{in} - 1) \times stride[2] - 2 \times padding[2] + kernel\_size[2] \\ \end{array} Args: kernel_size (Union[int, tuple[int]]): The size of kernel used to take the maximum value, an int number that represents depth, height and width of the kernel, or a tuple of three int numbers that represent depth, height and width respectively. stride (Union[int, tuple[int]]): The distance of kernel moving, an int number that represents the depth, height and width of movement are both stride, or a tuple of three int numbers that represent depth, height and width of movement respectively. If stride is None, then stride equal to kernel_size. Default: None. padding (Union[int, tuple[int]]): The pad value to be filled. Default: 0. If `padding` is an integer, the paddings of depth, height and width are the same, equal to padding. If `padding` is a tuple of three integers, the padding of depth, height and width equal to padding[0], padding[1] and padding[2] correspondingly. Inputs: - **x** (Tensor) - The input Tensor to invert. Tensor of shape :math:`(N, C, D_{in}, H_{in}, W_{in})` or :math:`(C, D_{in}, H_{in}, W_{in})`. - **indices** (Tensor) - Max values' index represented by the indices. Tensor of shape must be same with input 'x'. Values of indices must belong to :math:`[0, D_{in} \times H_{in} \times W_{in} - 1]`. Data type must be in int32 or int64. - **output_size** (tuple[int], optional) - The output size. Default: None. If output_size == (), then the shape of output computed by kernel_size, stride and padding. If output_size != (), then output_size must be :math:`(N, C, D, H, W)` , :math:`(C, D, H, W)` or :math:`(D, H, W)` and output_size must belong to :math:`[(N, C, D_{out} - stride[0], H_{out} - stride[1], W_{out} - stride[2]), (N, C, D_{out} + stride[0], H_{out} + stride[1], W_{out} + stride[2])]`. Outputs: Tensor, with shape :math:`(N, C, D_{out}, H_{out}, W_{out})` or :math:`(C, D_{out}, H_{out}, W_{out})`, with the same data type with `x`. Raises: TypeError: If data type of `x` or `indices` is not supported. TypeError: If `kernel_size`, `stride` or `padding` is neither an int nor a tuple. ValueError: If numbers in `stride` or `padding` (also support 0 and (0, 0, 0)) or `kernel_size` is not positive. ValueError: If the shape of `x` and `indices` are not equal. ValueError: If `kernel_size`, `stride` or `padding` is a tuple whose length is not equal to 3. ValueError: If `x` whose length is not 4 or 5. ValueError: If `output_size` whose length is not 0, 4 or 5. ValueError: If `output_size` whose type is not tuple. ValueError: If `output_size` is not close to output size computed by attr `kernel_size`, `stride`, `padding`. Supported Platforms: ``GPU`` ``CPU`` Examples: >>> x = Tensor(np.array([[[[[0, 1], [8, 9]]]]]).astype(np.float32)) >>> indices= Tensor(np.array([[[[[0, 1], [2, 3]]]]]).astype(np.int64)) >>> maxunpool3d = nn.MaxUnpool3d(kernel_size=1, stride=1, padding=0) >>> output = maxunpool3d(x, indices) >>> print(output.asnumpy()) [[[[[0. 1.] [8. 9.]]]]] """ def __init__(self, kernel_size, stride=None, padding=0): super(MaxUnpool3d, self).__init__() if stride is None: stride = kernel_size self.kernel_size = kernel_size self.stride = stride self.padding = padding def construct(self, x, indices, output_size=None): if output_size is None: output_size = () else: if not isinstance(output_size, tuple): raise ValueError(f"For MaxUnpool3d, output_size must be tuple, but type {type(output_size)}.") out = ops.max_unpool3d(x, indices, self.kernel_size, stride=self.stride, padding=self.padding, output_size=output_size) return out