Source code for mindspore.nn.layer.conv

# Copyright 2020 Huawei Technologies Co., Ltd
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# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
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# http://www.apache.org/licenses/LICENSE-2.0
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# ============================================================================
"""conv"""

import numpy as np
from mindspore import log as logger
from mindspore import context
from mindspore.ops import operations as P
from mindspore.ops.primitive import constexpr
from mindspore.common.parameter import Parameter
from mindspore.common.initializer import initializer, Initializer
from mindspore.common.tensor import Tensor
from mindspore._checkparam import ParamValidator as validator, Rel
from mindspore._checkparam import Validator
from mindspore._checkparam import check_bool, twice, check_int_positive
from mindspore._extends import cell_attr_register
from ..cell import Cell

__all__ = ['Conv2d', 'Conv2dTranspose', 'Conv1d', 'Conv1dTranspose']


class _Conv(Cell):
    """
    Applies a N-D convolution over an input signal composed of several input planes.
    """

    def __init__(self,
                 in_channels,
                 out_channels,
                 kernel_size,
                 stride,
                 pad_mode,
                 padding,
                 dilation,
                 group,
                 has_bias,
                 weight_init,
                 bias_init,
                 transposed=False):
        super(_Conv, self).__init__()
        self.in_channels = check_int_positive(in_channels)
        self.out_channels = check_int_positive(out_channels)
        self.kernel_size = kernel_size
        self.stride = stride
        self.pad_mode = pad_mode
        self.weight_init = weight_init
        self.bias_init = bias_init
        if isinstance(padding, int):
            Validator.check_integer('padding', padding, 0, Rel.GE, self.cls_name)
            self.padding = padding
        elif isinstance(padding, tuple):
            for pad in padding:
                Validator.check_integer('padding item', pad, 0, Rel.GE, self.cls_name)
            self.padding = padding
        else:
            raise TypeError("padding type must be int/tuple(int) cannot be {}!".format(type(padding)))

        self.dilation = dilation
        self.group = check_int_positive(group)
        self.has_bias = has_bias
        if (not isinstance(kernel_size[0], int)) or (not isinstance(kernel_size[1], int)) or \
                isinstance(kernel_size[0], bool) or isinstance(kernel_size[1], bool) or \
                kernel_size[0] < 1 or kernel_size[1] < 1:
            raise ValueError("Attr 'kernel_size' of 'Conv2D' Op passed "
                             + str(self.kernel_size) + ", should be a int or tuple and equal to or greater than 1.")
        if (not isinstance(stride[0], int)) or (not isinstance(stride[1], int)) or \
                isinstance(stride[0], bool) or isinstance(stride[1], bool) or stride[0] < 1 or stride[1] < 1:
            raise ValueError("Attr 'stride' of 'Conv2D' Op passed "
                             + str(self.stride) + ", should be a int or tuple and equal to or greater than 1.")
        if (not isinstance(dilation[0], int)) or (not isinstance(dilation[1], int)) or \
                isinstance(dilation[0], bool) or isinstance(dilation[1], bool) or dilation[0] < 1 or dilation[1] < 1:
            raise ValueError("Attr 'dilation' of 'Conv2D' Op passed "
                             + str(self.dilation) + ", should be a int or tuple and equal to or greater than 1.")
        if in_channels % group != 0:
            raise ValueError("Attr 'in_channels' of 'Conv2D' Op must be divisible by "
                             "attr 'group' of 'Conv2D' Op.")
        if out_channels % group != 0:
            raise ValueError("Attr 'out_channels' of 'Conv2D' Op must be divisible by "
                             "attr 'group' of 'Conv2D' Op.")
        if transposed:
            shape = [in_channels, out_channels // group, *kernel_size]
        else:
            shape = [out_channels, in_channels // group, *kernel_size]
        self.weight = Parameter(initializer(self.weight_init, shape), name='weight')

        if check_bool(has_bias):
            self.bias = Parameter(initializer(self.bias_init, [out_channels]), name='bias')
        else:
            if self.bias_init != 'zeros':
                logger.warning("Value of 'has_bias' is False, value of 'bias_init' will be ignored.")
            self.bias = None

    def construct(self, *inputs):
        """Must be overridden by all subclasses."""
        raise NotImplementedError


[docs]class Conv2d(_Conv): r""" 2D convolution layer. Applies a 2D convolution over an input tensor which is typically of shape :math:`(N, C_{in}, H_{in}, W_{in})`, where :math:`N` is batch size, :math:`C_{in}` is channel number, and :math:`H_{in}, W_{in})` are height and width. For each batch of shape :math:`(C_{in}, H_{in}, W_{in})`, the formula is defined as: .. math:: out_j = \sum_{i=0}^{C_{in} - 1} ccor(W_{ij}, X_i) + b_j, where :math:`ccor` is the cross-correlation operator, :math:`C_{in}` is the input channel number, :math:`j` ranges from :math:`0` to :math:`C_{out} - 1`, :math:`W_{ij}` corresponds to the :math:`i`-th channel of the :math:`j`-th filter and :math:`out_{j}` corresponds to the :math:`j`-th channel of the output. :math:`W_{ij}` is a slice of kernel and it has shape :math:`(\text{ks_h}, \text{ks_w})`, where :math:`\text{ks_h}` and :math:`\text{ks_w}` are the height and width of the convolution kernel. The full kernel has shape :math:`(C_{out}, C_{in} // \text{group}, \text{ks_h}, \text{ks_w})`, where group is the group number to split the input in the channel dimension. If the 'pad_mode' is set to be "valid", the output height and width will be :math:`\left \lfloor{1 + \frac{H_{in} + 2 \times \text{padding} - \text{ks_h} - (\text{ks_h} - 1) \times (\text{dilation} - 1) }{\text{stride}}} \right \rfloor` and :math:`\left \lfloor{1 + \frac{W_{in} + 2 \times \text{padding} - \text{ks_w} - (\text{ks_w} - 1) \times (\text{dilation} - 1) }{\text{stride}}} \right \rfloor` respectively. The first introduction can be found in paper `Gradient Based Learning Applied to Document Recognition <http://vision.stanford.edu/cs598_spring07/papers/Lecun98.pdf>`_. Args: in_channels (int): The number of input channel :math:`C_{in}`. out_channels (int): The number of output channel :math:`C_{out}`. kernel_size (Union[int, tuple[int]]): The data type is int or a tuple of 2 integers. Specifies the height and width of the 2D convolution window. Single int means the value is for both the height and the width of the kernel. A tuple of 2 ints means the first value is for the height and the other is for the width of the kernel. stride (Union[int, tuple[int]]): The distance of kernel moving, an int number 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 padding mode. The optional values are "same", "valid", "pad". Default: "same". - same: Adopts the way of completion. The height and width of the output will be the same as the input. 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. If this mode is set, `padding` must be 0. - valid: Adopts the way of discarding. The possible largest height and width of output will be returned without padding. Extra pixels will be discarded. If this mode is set, `padding` must be 0. - pad: Implicit paddings on both sides of the input. The number of `padding` will be padded to the input Tensor borders. `padding` must be greater than or equal to 0. padding (Union[int, tuple[int]]): Implicit paddings on both sides of the input. If `padding` is one integer, the paddings of top, bottom, left and right are the same, equal to padding. If `padding` is a tuple with four integers, the paddings of top, bottom, left and right will be equal to padding[0], padding[1], padding[2], and padding[3] accordingly. Default: 0. dilation (Union[int, tuple[int]]): The data type is int or a tuple of 2 integers. Specifies the dilation rate to use for dilated convolution. If set to be :math:`k > 1`, there will be :math:`k - 1` pixels skipped for each sampling location. Its value must be greater or equal to 1 and bounded by the height and width of the input. Default: 1. group (int): Splits filter into groups, `in_ channels` and `out_channels` must be divisible by the number of groups. If the group is equal to `in_channels` and `out_channels`, this 2D convolution layer also can be called 2D depthwise convolution layer. Default: 1. has_bias (bool): Specifies whether the layer uses a bias vector. Default: False. weight_init (Union[Tensor, str, Initializer, numbers.Number]): Initializer for the convolution kernel. It can be a Tensor, a string, an Initializer or a number. When a string is specified, values from 'TruncatedNormal', 'Normal', 'Uniform', 'HeUniform' and 'XavierUniform' distributions as well as constant 'One' and 'Zero' distributions are possible. Alias 'xavier_uniform', 'he_uniform', 'ones' and 'zeros' are acceptable. Uppercase and lowercase are both acceptable. Refer to the values of Initializer for more details. Default: 'normal'. bias_init (Union[Tensor, str, Initializer, numbers.Number]): Initializer for the bias vector. Possible Initializer and string are the same as 'weight_init'. Refer to the values of Initializer for more details. Default: 'zeros'. Inputs: - **input** (Tensor) - Tensor of shape :math:`(N, C_{in}, H_{in}, W_{in})`. Outputs: Tensor of shape :math:`(N, C_{out}, H_{out}, W_{out})`. Examples: >>> net = nn.Conv2d(120, 240, 4, has_bias=False, weight_init='normal') >>> input = Tensor(np.ones([1, 120, 1024, 640]), mindspore.float32) >>> net(input).shape (1, 240, 1024, 640) """ @cell_attr_register def __init__(self, in_channels, out_channels, kernel_size, stride=1, pad_mode='same', padding=0, dilation=1, group=1, has_bias=False, weight_init='normal', bias_init='zeros'): kernel_size = twice(kernel_size) stride = twice(stride) self._dilation = dilation dilation = twice(dilation) super(Conv2d, self).__init__( in_channels, out_channels, kernel_size, stride, pad_mode, padding, dilation, group, has_bias, weight_init, bias_init) self.conv2d = P.Conv2D(out_channel=self.out_channels, kernel_size=self.kernel_size, mode=1, pad_mode=self.pad_mode, pad=self.padding, stride=self.stride, dilation=self.dilation, group=self.group) self._init_depthwise_conv2d() self.bias_add = P.BiasAdd() def _init_depthwise_conv2d(self): """Initialize depthwise conv2d op""" if context.get_context("device_target") == "Ascend" and self.group > 1: self.dilation = self._dilation validator.check_integer('group', self.group, self.in_channels, Rel.EQ) validator.check_integer('group', self.group, self.out_channels, Rel.EQ) self.conv2d = P.DepthwiseConv2dNative(channel_multiplier=1, kernel_size=self.kernel_size, pad_mode=self.pad_mode, pad=self.padding, stride=self.stride, dilation=self.dilation) weight_shape = [1, self.in_channels, *self.kernel_size] if isinstance(self.weight_init, Tensor): self.weight_init = Tensor(self.weight_init.asnumpy().swapaxes(0, 1), self.weight_init.dtype) if isinstance(self.weight_init, Initializer): self.weight_init.shape = weight_shape self.weight = Parameter(initializer(self.weight_init, weight_shape), name='weight') def construct(self, x): output = self.conv2d(x, self.weight) if self.has_bias: output = self.bias_add(output, self.bias) return output def extend_repr(self): s = 'input_channels={}, output_channels={}, kernel_size={},' \ 'stride={}, pad_mode={}, padding={}, dilation={}, ' \ 'group={}, has_bias={},' \ 'weight_init={}, bias_init={}'.format( self.in_channels, self.out_channels, self.kernel_size, self.stride, self.pad_mode, self.padding, self.dilation, self.group, self.has_bias, self.weight_init, self.bias_init) return s
@constexpr def _check_input_3d(input_shape): if len(input_shape) != 3: raise ValueError(f"Input should be 3d, but got shape {input_shape}")
[docs]class Conv1d(_Conv): r""" 1D convolution layer. Applies a 1D convolution over an input tensor which is typically of shape :math:`(N, C_{in}, W_{in})`, where :math:`N` is batch size and :math:`C_{in}` is channel number. For each batch of shape :math:`(C_{in}, W_{in})`, the formula is defined as: .. math:: out_j = \sum_{i=0}^{C_{in} - 1} ccor(W_{ij}, X_i) + b_j, where :math:`ccor` is the cross correlation operator, :math:`C_{in}` is the input channel number, :math:`j` ranges from :math:`0` to :math:`C_{out} - 1`, :math:`W_{ij}` corresponds to the :math:`i`-th channel of the :math:`j`-th filter and :math:`out_{j}` corresponds to the :math:`j`-th channel of the output. :math:`W_{ij}` is a slice of kernel and it has shape :math:`(\text{ks_w})`, where :math:`\text{ks_w}` is the width of the convolution kernel. The full kernel has shape :math:`(C_{out}, C_{in} // \text{group}, \text{ks_w})`, where group is the group number to split the input in the channel dimension. If the 'pad_mode' is set to be "valid", the output width will be :math:`\left \lfloor{1 + \frac{W_{in} + 2 \times \text{padding} - \text{ks_w} - (\text{ks_w} - 1) \times (\text{dilation} - 1) }{\text{stride}}} \right \rfloor` respectively. The first introduction of convolution layer can be found in paper `Gradient Based Learning Applied to Document Recognition <http://vision.stanford.edu/cs598_spring07/papers/Lecun98.pdf>`_. Args: in_channels (int): The number of input channel :math:`C_{in}`. out_channels (int): The number of output channel :math:`C_{out}`. kernel_size (int): The data type is int. Specifies the width of the 1D convolution window. stride (int): The distance of kernel moving, an int number that represents the width of movement. Default: 1. pad_mode (str): Specifies padding mode. The optional values are "same", "valid", "pad". Default: "same". - same: Adopts the way of completion. The output width will be the same as the input. The total number of padding will be calculated in the horizontal direction and evenly distributed to left and right if possible. Otherwise, the last extra padding will be done from the bottom and the right side. If this mode is set, `padding` must be 0. - valid: Adopts the way of discarding. The possible largest width of the output will be returned without padding. Extra pixels will be discarded. If this mode is set, `padding` must be 0. - pad: Implicit paddings on both sides of the input. The number of `padding` will be padded to the input Tensor borders. `padding` must be greater than or equal to 0. padding (int): Implicit paddings on both sides of the input. Default: 0. dilation (int): The data type is int. Specifies the dilation rate to use for dilated convolution. If set to be :math:`k > 1`, there will be :math:`k - 1` pixels skipped for each sampling location. Its value must be greater or equal to 1 and bounded by the height and width of the input. Default: 1. group (int): Splits filter into groups, `in_ channels` and `out_channels` must be divisible by the number of groups. Default: 1. has_bias (bool): Specifies whether the layer uses a bias vector. Default: False. weight_init (Union[Tensor, str, Initializer, numbers.Number]): An initializer for the convolution kernel. It can be a Tensor, a string, an Initializer or a number. When a string is specified, values from 'TruncatedNormal', 'Normal', 'Uniform', 'HeUniform' and 'XavierUniform' distributions as well as constant 'One' and 'Zero' distributions are possible. Alias 'xavier_uniform', 'he_uniform', 'ones' and 'zeros' are acceptable. Uppercase and lowercase are both acceptable. Refer to the values of Initializer for more details. Default: 'normal'. bias_init (Union[Tensor, str, Initializer, numbers.Number]): Initializer for the bias vector. Possible Initializer and string are the same as 'weight_init'. Refer to the values of Initializer for more details. Default: 'zeros'. Inputs: - **input** (Tensor) - Tensor of shape :math:`(N, C_{in}, W_{in})`. Outputs: Tensor of shape :math:`(N, C_{out}, W_{out})`. Examples: >>> net = nn.Conv1d(120, 240, 4, has_bias=False, weight_init='normal') >>> input = Tensor(np.ones([1, 120, 640]), mindspore.float32) >>> net(input).shape (1, 240, 640) """ @cell_attr_register def __init__(self, in_channels, out_channels, kernel_size, stride=1, pad_mode='same', padding=0, dilation=1, group=1, has_bias=False, weight_init='normal', bias_init='zeros'): Validator.check_value_type("kernel_size", kernel_size, [int], self.cls_name) Validator.check_value_type("stride", stride, [int], self.cls_name) Validator.check_value_type("padding", padding, [int], self.cls_name) Validator.check_value_type("dilation", dilation, [int], self.cls_name) Validator.check_integer('kernel_size', kernel_size, 1, Rel.GE, self.cls_name) Validator.check_integer('stride', stride, 1, Rel.GE, self.cls_name) Validator.check_integer('padding', padding, 0, Rel.GE, self.cls_name) Validator.check_integer('dilation', dilation, 1, Rel.GE, self.cls_name) kernel_size = (1, kernel_size) stride = (1, stride) dilation = (1, dilation) get_shape = P.Shape() get_dtype = P.DType() if isinstance(weight_init, Tensor): weight_init_shape = get_shape(weight_init) Validator.check_integer('weight_init_shape', len(weight_init_shape), 3, Rel.EQ, self.cls_name) weight_init_dtype = get_dtype(weight_init) weight_init_value = weight_init.asnumpy() weight_init_value = np.expand_dims(weight_init_value, 2) weight_init = Tensor(weight_init_value, weight_init_dtype) super(Conv1d, self).__init__( in_channels, out_channels, kernel_size, stride, pad_mode, padding, dilation, group, has_bias, weight_init, bias_init) self.padding = (0, 0, padding, padding) self.conv2d = P.Conv2D(out_channel=self.out_channels, kernel_size=self.kernel_size, mode=1, pad_mode=self.pad_mode, pad=self.padding, stride=self.stride, dilation=self.dilation, group=self.group) self.bias_add = P.BiasAdd() if pad_mode not in ('valid', 'same', 'pad'): raise ValueError('Attr \'pad_mode\' of \'Conv1d\' Op passed ' + str(pad_mode) + ', should be one of values in \'valid\', \'same\', \'pad\'.') self.expand_dims = P.ExpandDims() self.squeeze = P.Squeeze(2) self.shape = P.Shape() def construct(self, x): x_shape = self.shape(x) _check_input_3d(x_shape) x = self.expand_dims(x, 2) output = self.conv2d(x, self.weight) if self.has_bias: output = self.bias_add(output, self.bias) output = self.squeeze(output) return output def extend_repr(self): s = 'input_channels={}, output_channels={}, kernel_size={},' \ 'stride={}, pad_mode={}, padding={}, dilation={}, ' \ 'group={}, has_bias={},' \ 'weight_init={}, bias_init={}'.format( self.in_channels, self.out_channels, self.kernel_size, self.stride, self.pad_mode, self.padding, self.dilation, self.group, self.has_bias, self.weight_init, self.bias_init) return s
[docs]class Conv2dTranspose(_Conv): r""" 2D transposed convolution layer. Compute a 2D transposed convolution, which is also known as a deconvolution (although it is not an actual deconvolution). Input is typically of shape :math:`(N, C, H, W)`, where :math:`N` is batch size and :math:`C` is channel number. Args: in_channels (int): The number of channels in the input space. out_channels (int): The number of channels in the output space. kernel_size (Union[int, tuple]): int or a tuple of 2 integers, which specifies the height and width of the 2D convolution window. Single int means the value is for both the height and the width of the kernel. A tuple of 2 ints means the first value is for the height and the other is for the width of the kernel. stride (Union[int, tuple[int]]): The distance of kernel moving, an int number 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. Its value must be equal to or greater than 1. Default: 1. pad_mode (str): Select the mode of the pad. The optional values are "pad", "same", "valid". Default: "same". - pad: Implicit paddings on both sides of the input. - same: Adopted the way of completion. - valid: Adopted the way of discarding. padding (Union[int, tuple[int]]): Implicit paddings on both sides of the input. If `padding` is one integer, the paddings of top, bottom, left and right are the same, equal to padding. If `padding` is a tuple with four integers, the paddings of top, bottom, left and right will be equal to padding[0], padding[1], padding[2], and padding[3] accordingly. Default: 0. dilation (Union[int, tuple[int]]): The data type is int or a tuple of 2 integers. Specifies the dilation rate to use for dilated convolution. If set to be :math:`k > 1`, there will be :math:`k - 1` pixels skipped for each sampling location. Its value must be greater than or equal to 1 and bounded by the height and width of the input. Default: 1. group (int): Splits filter into groups, `in_channels` and `out_channels` must be divisible by the number of groups. This does not support for Davinci devices when group > 1. Default: 1. has_bias (bool): Specifies whether the layer uses a bias vector. Default: False. weight_init (Union[Tensor, str, Initializer, numbers.Number]): Initializer for the convolution kernel. It can be a Tensor, a string, an Initializer or a number. When a string is specified, values from 'TruncatedNormal', 'Normal', 'Uniform', 'HeUniform' and 'XavierUniform' distributions as well as constant 'One' and 'Zero' distributions are possible. Alias 'xavier_uniform', 'he_uniform', 'ones' and 'zeros' are acceptable. Uppercase and lowercase are both acceptable. Refer to the values of Initializer for more details. Default: 'normal'. bias_init (Union[Tensor, str, Initializer, numbers.Number]): Initializer for the bias vector. Possible Initializer and string are the same as 'weight_init'. Refer to the values of Initializer for more details. Default: 'zeros'. Inputs: - **input** (Tensor) - Tensor of shape :math:`(N, C_{in}, H_{in}, W_{in})`. Outputs: Tensor of shape :math:`(N, C_{out}, H_{out}, W_{out})`. Examples: >>> net = nn.Conv2dTranspose(3, 64, 4, has_bias=False, weight_init='normal') >>> input = Tensor(np.ones([1, 3, 16, 50]), mindspore.float32) >>> net(input) """ def __init__(self, in_channels, out_channels, kernel_size, stride=1, pad_mode='same', padding=0, dilation=1, group=1, has_bias=False, weight_init='normal', bias_init='zeros'): kernel_size = twice(kernel_size) stride = twice(stride) dilation = twice(dilation) Validator.check_value_type('padding', padding, (int, tuple), self.cls_name) if isinstance(padding, tuple): Validator.check_integer('padding size', len(padding), 4, Rel.EQ, self.cls_name) # out_channels and in_channels swap. # cause Conv2DBackpropInput's out_channel refers to Conv2D's out_channel, # then Conv2dTranspose's out_channel refers to Conv2DBackpropInput's in_channel. super(Conv2dTranspose, self).__init__( in_channels, out_channels, kernel_size, stride, pad_mode, padding, dilation, group, has_bias, weight_init, bias_init, transposed=True) self.in_channels = in_channels self.out_channels = out_channels self.shape = P.Shape() if pad_mode not in ('valid', 'same', 'pad'): raise ValueError('Attr \'pad_mode\' of \'Conv2dTranspose\' Op passed ' + str(pad_mode) + ', should be one of values in \'valid\', \'same\', \'pad\'.') self.is_valid = self.pad_mode == 'valid' self.is_same = self.pad_mode == 'same' self.is_pad = self.pad_mode == 'pad' if check_bool(has_bias): self.bias = Parameter(initializer(bias_init, [out_channels]), name='bias') # cause Conv2DBackpropInput's out_channel refers to Conv2D's out_channel. self.conv2d_transpose = P.Conv2DBackpropInput(out_channel=in_channels, kernel_size=kernel_size, mode=1, pad_mode=pad_mode, pad=padding, stride=stride, dilation=dilation, group=group) self.bias_add = P.BiasAdd() if isinstance(self.padding, int): self.padding_top, self.padding_bottom, self.padding_left, self.padding_right = (self.padding,) * 4 else: self.padding_top, self.padding_bottom, self.padding_left, self.padding_right = self.padding def shard(self, strategy): self.conv2d_transpose.shard(strategy) return self def _deconv_output_length(self, input_length, filter_size, stride_size, dilation_size, padding): """Calculate the width and height of output.""" length = 0 filter_size = filter_size + (filter_size - 1) * (dilation_size - 1) if self.is_valid: if filter_size - stride_size > 0: length = input_length * stride_size + filter_size - stride_size else: length = input_length * stride_size elif self.is_same: length = input_length * stride_size elif self.is_pad: length = input_length * stride_size - padding + filter_size - stride_size return length def construct(self, x): n, _, h, w = self.shape(x) h_out = self._deconv_output_length(h, self.kernel_size[0], self.stride[0], self.dilation[0], self.padding_top + self.padding_bottom) w_out = self._deconv_output_length(w, self.kernel_size[1], self.stride[1], self.dilation[1], self.padding_left + self.padding_right) if self.has_bias: return self.bias_add(self.conv2d_transpose(x, self.weight, (n, self.out_channels, h_out, w_out)), self.bias) return self.conv2d_transpose(x, self.weight, (n, self.out_channels, h_out, w_out)) def extend_repr(self): s = 'input_channels={}, output_channels={}, kernel_size={},' \ 'stride={}, pad_mode={}, padding={}, dilation={}, ' \ 'group={}, has_bias={},' \ 'weight_init={}, bias_init={}'.format(self.in_channels, self.out_channels, self.kernel_size, self.stride, self.pad_mode, self.padding, self.dilation, self.group, self.has_bias, self.weight_init, self.bias_init) return s
[docs]class Conv1dTranspose(_Conv): r""" 1D transposed convolution layer. Compute a 1D transposed convolution, which is also known as a deconvolution (although it is not an actual deconvolution). Input is typically of shape :math:`(N, C, W)`, where :math:`N` is batch size and :math:`C` is channel number. Args: in_channels (int): The number of channels in the input space. out_channels (int): The number of channels in the output space. kernel_size (int): int, which specifies the width of the 1D convolution window. stride (int): The distance of kernel moving, an int number that represents the width of movement. Default: 1. pad_mode (str): Select the mode of the pad. The optional values are "pad", "same", "valid". Default: "same". - pad: Implicit paddings on both sides of the input. - same: Adopted the way of completion. - valid: Adopted the way of discarding. padding (int): Implicit paddings on both sides of the input. Default: 0. dilation (int): The data type is int. Specifies the dilation rate to use for dilated convolution. If set to be :math:`k > 1`, there will be :math:`k - 1` pixels skipped for each sampling location. Its value must be greater or equal to 1 and bounded by the width of the input. Default: 1. group (int): Splits filter into groups, `in_channels` and `out_channels` must be divisible by the number of groups. This is not support for Davinci devices when group > 1. Default: 1. has_bias (bool): Specifies whether the layer uses a bias vector. Default: False. weight_init (Union[Tensor, str, Initializer, numbers.Number]): Initializer for the convolution kernel. It can be a Tensor, a string, an Initializer or a numbers.Number. When a string is specified, values from 'TruncatedNormal', 'Normal', 'Uniform', 'HeUniform' and 'XavierUniform' distributions as well as constant 'One' and 'Zero' distributions are possible. Alias 'xavier_uniform', 'he_uniform', 'ones' and 'zeros' are acceptable. Uppercase and lowercase are both acceptable. Refer to the values of Initializer for more details. Default: 'normal'. bias_init (Union[Tensor, str, Initializer, numbers.Number]): Initializer for the bias vector. Possible Initializer and string are the same as 'weight_init'. Refer to the values of Initializer for more details. Default: 'zeros'. Inputs: - **input** (Tensor) - Tensor of shape :math:`(N, C_{in}, W_{in})`. Outputs: Tensor of shape :math:`(N, C_{out}, W_{out})`. Examples: >>> net = nn.Conv1dTranspose(3, 64, 4, has_bias=False, weight_init='normal') >>> input = Tensor(np.ones([1, 3, 50]), mindspore.float32) >>> net(input) """ def __init__(self, in_channels, out_channels, kernel_size, stride=1, pad_mode='same', padding=0, dilation=1, group=1, has_bias=False, weight_init='normal', bias_init='zeros'): Validator.check_value_type("kernel_size", kernel_size, [int], self.cls_name) Validator.check_value_type("stride", stride, [int], self.cls_name) Validator.check_value_type("padding", padding, [int], self.cls_name) Validator.check_value_type("dilation", dilation, [int], self.cls_name) Validator.check_integer('kernel_size', kernel_size, 1, Rel.GE, self.cls_name) Validator.check_integer('stride', stride, 1, Rel.GE, self.cls_name) Validator.check_integer('padding', padding, 0, Rel.GE, self.cls_name) Validator.check_integer('dilation', dilation, 1, Rel.GE, self.cls_name) kernel_size = (1, kernel_size) stride = (1, stride) dilation = (1, dilation) get_shape = P.Shape() get_dtype = P.DType() if isinstance(weight_init, Tensor): weight_init_shape = get_shape(weight_init) Validator.check_integer('weight_init_shape', len(weight_init_shape), 3, Rel.EQ, self.cls_name) weight_init_dtype = get_dtype(weight_init) weight_init_value = weight_init.asnumpy() weight_init_value = np.expand_dims(weight_init_value, 2) weight_init = Tensor(weight_init_value, weight_init_dtype) # out_channels and in_channels swap. # cause Conv2DBackpropInput's out_channel refers to Conv2D's out_channel, # then Conv1dTranspose's out_channel refers to Conv2DBackpropInput's in_channel. super(Conv1dTranspose, self).__init__( in_channels, out_channels, kernel_size, stride, pad_mode, padding, dilation, group, has_bias, weight_init, bias_init, transposed=True) self.padding = (0, 0, padding, padding) self.in_channels = in_channels self.out_channels = out_channels self.shape = P.Shape() if pad_mode not in ('valid', 'same', 'pad'): raise ValueError('Attr \'pad_mode\' of \'Conv1dTranspose\' Op passed ' + str(pad_mode) + ', should be one of values in \'valid\', \'same\', \'pad\'.') self.is_valid = self.pad_mode == 'valid' self.is_same = self.pad_mode == 'same' self.is_pad = self.pad_mode == 'pad' if check_bool(has_bias): self.bias = Parameter(initializer(bias_init, [out_channels]), name='bias') # cause Conv2DBackpropInput's out_channel refers to Conv2D's out_channel. self.conv2d_transpose = P.Conv2DBackpropInput(out_channel=in_channels, kernel_size=kernel_size, mode=1, pad_mode=pad_mode, pad=self.padding, stride=stride, dilation=dilation, group=group) self.bias_add = P.BiasAdd() self.expand_dims = P.ExpandDims() self.squeeze = P.Squeeze(2) def shard(self, strategy): self.conv2d_transpose.shard(strategy) return self def _deconv_output_length(self, input_length, filter_size, stride_size, dilation_size, padding): """Calculate the width and height of output.""" length = 0 filter_size = filter_size + (filter_size - 1) * (dilation_size - 1) if self.is_valid: if filter_size - stride_size > 0: length = input_length * stride_size + filter_size - stride_size else: length = input_length * stride_size elif self.is_same: length = input_length * stride_size elif self.is_pad: length = input_length * stride_size - padding + filter_size - stride_size return length def construct(self, x): x_shape = self.shape(x) _check_input_3d(x_shape) x = self.expand_dims(x, 2) n, _, h, w = self.shape(x) h_out = self._deconv_output_length(h, self.kernel_size[0], self.stride[0], self.dilation[0], self.padding[0] + self.padding[1]) w_out = self._deconv_output_length(w, self.kernel_size[1], self.stride[1], self.dilation[1], self.padding[2] + self.padding[3]) output = self.conv2d_transpose(x, self.weight, (n, self.out_channels, h_out, w_out)) if self.has_bias: output = self.bias_add(output, self.bias) output = self.squeeze(output) return output def extend_repr(self): s = 'input_channels={}, output_channels={}, kernel_size={},' \ 'stride={}, pad_mode={}, padding={}, dilation={}, ' \ 'group={}, has_bias={},' \ 'weight_init={}, bias_init={}'.format(self.in_channels, self.out_channels, self.kernel_size, self.stride, self.pad_mode, self.padding, self.dilation, self.group, self.has_bias, self.weight_init, self.bias_init) return s