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# coding: utf-8

"""
This file defines various neural network modules and utility functions, including convolutional and residual blocks,
normalizations, and functions for spatial transformation and tensor manipulation.
"""

from torch import nn
import torch.nn.functional as F
import torch
import torch.nn.utils.spectral_norm as spectral_norm
import math
import warnings


def kp2gaussian(kp, spatial_size, kp_variance):
    """
    Transform a keypoint into gaussian like representation
    """
    mean = kp

    coordinate_grid = make_coordinate_grid(spatial_size, mean)
    number_of_leading_dimensions = len(mean.shape) - 1
    shape = (1,) * number_of_leading_dimensions + coordinate_grid.shape
    coordinate_grid = coordinate_grid.view(*shape)
    repeats = mean.shape[:number_of_leading_dimensions] + (1, 1, 1, 1)
    coordinate_grid = coordinate_grid.repeat(*repeats)

    # Preprocess kp shape
    shape = mean.shape[:number_of_leading_dimensions] + (1, 1, 1, 3)
    mean = mean.view(*shape)

    mean_sub = (coordinate_grid - mean)

    out = torch.exp(-0.5 * (mean_sub ** 2).sum(-1) / kp_variance)

    return out


def make_coordinate_grid(spatial_size, ref, **kwargs):
    d, h, w = spatial_size
    x = torch.arange(w).type(ref.dtype).to(ref.device)
    y = torch.arange(h).type(ref.dtype).to(ref.device)
    z = torch.arange(d).type(ref.dtype).to(ref.device)

    # NOTE: must be right-down-in
    x = (2 * (x / (w - 1)) - 1)  # the x axis faces to the right
    y = (2 * (y / (h - 1)) - 1)  # the y axis faces to the bottom
    z = (2 * (z / (d - 1)) - 1)  # the z axis faces to the inner

    yy = y.view(1, -1, 1).repeat(d, 1, w)
    xx = x.view(1, 1, -1).repeat(d, h, 1)
    zz = z.view(-1, 1, 1).repeat(1, h, w)

    meshed = torch.cat([xx.unsqueeze_(3), yy.unsqueeze_(3), zz.unsqueeze_(3)], 3)

    return meshed


class ConvT2d(nn.Module):
    """
    Upsampling block for use in decoder.
    """

    def __init__(self, in_features, out_features, kernel_size=3, stride=2, padding=1, output_padding=1):
        super(ConvT2d, self).__init__()

        self.convT = nn.ConvTranspose2d(in_features, out_features, kernel_size=kernel_size, stride=stride,
                                        padding=padding, output_padding=output_padding)
        self.norm = nn.InstanceNorm2d(out_features)

    def forward(self, x):
        out = self.convT(x)
        out = self.norm(out)
        out = F.leaky_relu(out)
        return out


class ResBlock3d(nn.Module):
    """
    Res block, preserve spatial resolution.
    """

    def __init__(self, in_features, kernel_size, padding):
        super(ResBlock3d, self).__init__()
        self.conv1 = nn.Conv3d(in_channels=in_features, out_channels=in_features, kernel_size=kernel_size, padding=padding)
        self.conv2 = nn.Conv3d(in_channels=in_features, out_channels=in_features, kernel_size=kernel_size, padding=padding)
        self.norm1 = nn.BatchNorm3d(in_features, affine=True)
        self.norm2 = nn.BatchNorm3d(in_features, affine=True)

    def forward(self, x):
        out = self.norm1(x)
        out = F.relu(out)
        out = self.conv1(out)
        out = self.norm2(out)
        out = F.relu(out)
        out = self.conv2(out)
        out += x
        return out


class UpBlock3d(nn.Module):
    """
    Upsampling block for use in decoder.
    """

    def __init__(self, in_features, out_features, kernel_size=3, padding=1, groups=1):
        super(UpBlock3d, self).__init__()

        self.conv = nn.Conv3d(in_channels=in_features, out_channels=out_features, kernel_size=kernel_size,
                              padding=padding, groups=groups)
        self.norm = nn.BatchNorm3d(out_features, affine=True)

    def forward(self, x):
        out = F.interpolate(x, scale_factor=(1, 2, 2))
        out = self.conv(out)
        out = self.norm(out)
        out = F.relu(out)
        return out


class DownBlock2d(nn.Module):
    """
    Downsampling block for use in encoder.
    """

    def __init__(self, in_features, out_features, kernel_size=3, padding=1, groups=1):
        super(DownBlock2d, self).__init__()
        self.conv = nn.Conv2d(in_channels=in_features, out_channels=out_features, kernel_size=kernel_size, padding=padding, groups=groups)
        self.norm = nn.BatchNorm2d(out_features, affine=True)
        self.pool = nn.AvgPool2d(kernel_size=(2, 2))

    def forward(self, x):
        out = self.conv(x)
        out = self.norm(out)
        out = F.relu(out)
        out = self.pool(out)
        return out


class DownBlock3d(nn.Module):
    """
    Downsampling block for use in encoder.
    """

    def __init__(self, in_features, out_features, kernel_size=3, padding=1, groups=1):
        super(DownBlock3d, self).__init__()
        '''
        self.conv = nn.Conv3d(in_channels=in_features, out_channels=out_features, kernel_size=kernel_size,
                                padding=padding, groups=groups, stride=(1, 2, 2))
        '''
        self.conv = nn.Conv3d(in_channels=in_features, out_channels=out_features, kernel_size=kernel_size,
                              padding=padding, groups=groups)
        self.norm = nn.BatchNorm3d(out_features, affine=True)
        self.pool = nn.AvgPool3d(kernel_size=(1, 2, 2))

    def forward(self, x):
        out = self.conv(x)
        out = self.norm(out)
        out = F.relu(out)
        out = self.pool(out)
        return out


class SameBlock2d(nn.Module):
    """
    Simple block, preserve spatial resolution.
    """

    def __init__(self, in_features, out_features, groups=1, kernel_size=3, padding=1, lrelu=False):
        super(SameBlock2d, self).__init__()
        self.conv = nn.Conv2d(in_channels=in_features, out_channels=out_features, kernel_size=kernel_size, padding=padding, groups=groups)
        self.norm = nn.BatchNorm2d(out_features, affine=True)
        if lrelu:
            self.ac = nn.LeakyReLU()
        else:
            self.ac = nn.ReLU()

    def forward(self, x):
        out = self.conv(x)
        out = self.norm(out)
        out = self.ac(out)
        return out


class Encoder(nn.Module):
    """
    Hourglass Encoder
    """

    def __init__(self, block_expansion, in_features, num_blocks=3, max_features=256):
        super(Encoder, self).__init__()

        down_blocks = []
        for i in range(num_blocks):
            down_blocks.append(DownBlock3d(in_features if i == 0 else min(max_features, block_expansion * (2 ** i)), min(max_features, block_expansion * (2 ** (i + 1))), kernel_size=3, padding=1))
        self.down_blocks = nn.ModuleList(down_blocks)

    def forward(self, x):
        outs = [x]
        for down_block in self.down_blocks:
            outs.append(down_block(outs[-1]))
        return outs


class Decoder(nn.Module):
    """
    Hourglass Decoder
    """

    def __init__(self, block_expansion, in_features, num_blocks=3, max_features=256):
        super(Decoder, self).__init__()

        up_blocks = []

        for i in range(num_blocks)[::-1]:
            in_filters = (1 if i == num_blocks - 1 else 2) * min(max_features, block_expansion * (2 ** (i + 1)))
            out_filters = min(max_features, block_expansion * (2 ** i))
            up_blocks.append(UpBlock3d(in_filters, out_filters, kernel_size=3, padding=1))

        self.up_blocks = nn.ModuleList(up_blocks)
        self.out_filters = block_expansion + in_features

        self.conv = nn.Conv3d(in_channels=self.out_filters, out_channels=self.out_filters, kernel_size=3, padding=1)
        self.norm = nn.BatchNorm3d(self.out_filters, affine=True)

    def forward(self, x):
        out = x.pop()
        for up_block in self.up_blocks:
            out = up_block(out)
            skip = x.pop()
            out = torch.cat([out, skip], dim=1)
        out = self.conv(out)
        out = self.norm(out)
        out = F.relu(out)
        return out


class Hourglass(nn.Module):
    """
    Hourglass architecture.
    """

    def __init__(self, block_expansion, in_features, num_blocks=3, max_features=256):
        super(Hourglass, self).__init__()
        self.encoder = Encoder(block_expansion, in_features, num_blocks, max_features)
        self.decoder = Decoder(block_expansion, in_features, num_blocks, max_features)
        self.out_filters = self.decoder.out_filters

    def forward(self, x):
        return self.decoder(self.encoder(x))


class SPADE(nn.Module):
    def __init__(self, norm_nc, label_nc):
        super().__init__()

        self.param_free_norm = nn.InstanceNorm2d(norm_nc, affine=False)
        nhidden = 128

        self.mlp_shared = nn.Sequential(
            nn.Conv2d(label_nc, nhidden, kernel_size=3, padding=1),
            nn.ReLU())
        self.mlp_gamma = nn.Conv2d(nhidden, norm_nc, kernel_size=3, padding=1)
        self.mlp_beta = nn.Conv2d(nhidden, norm_nc, kernel_size=3, padding=1)

    def forward(self, x, segmap):
        normalized = self.param_free_norm(x)
        segmap = F.interpolate(segmap, size=x.size()[2:], mode='nearest')
        actv = self.mlp_shared(segmap)
        gamma = self.mlp_gamma(actv)
        beta = self.mlp_beta(actv)
        out = normalized * (1 + gamma) + beta
        return out


class SPADEResnetBlock(nn.Module):
    def __init__(self, fin, fout, norm_G, label_nc, use_se=False, dilation=1):
        super().__init__()
        # Attributes
        self.learned_shortcut = (fin != fout)
        fmiddle = min(fin, fout)
        self.use_se = use_se
        # create conv layers
        self.conv_0 = nn.Conv2d(fin, fmiddle, kernel_size=3, padding=dilation, dilation=dilation)
        self.conv_1 = nn.Conv2d(fmiddle, fout, kernel_size=3, padding=dilation, dilation=dilation)
        if self.learned_shortcut:
            self.conv_s = nn.Conv2d(fin, fout, kernel_size=1, bias=False)
        # apply spectral norm if specified
        if 'spectral' in norm_G:
            self.conv_0 = spectral_norm(self.conv_0)
            self.conv_1 = spectral_norm(self.conv_1)
            if self.learned_shortcut:
                self.conv_s = spectral_norm(self.conv_s)
        # define normalization layers
        self.norm_0 = SPADE(fin, label_nc)
        self.norm_1 = SPADE(fmiddle, label_nc)
        if self.learned_shortcut:
            self.norm_s = SPADE(fin, label_nc)

    def forward(self, x, seg1):
        x_s = self.shortcut(x, seg1)
        dx = self.conv_0(self.actvn(self.norm_0(x, seg1)))
        dx = self.conv_1(self.actvn(self.norm_1(dx, seg1)))
        out = x_s + dx
        return out

    def shortcut(self, x, seg1):
        if self.learned_shortcut:
            x_s = self.conv_s(self.norm_s(x, seg1))
        else:
            x_s = x
        return x_s

    def actvn(self, x):
        return F.leaky_relu(x, 2e-1)


def filter_state_dict(state_dict, remove_name='fc'):
    new_state_dict = {}
    for key in state_dict:
        if remove_name in key:
            continue
        new_state_dict[key] = state_dict[key]
    return new_state_dict


class GRN(nn.Module):
    """ GRN (Global Response Normalization) layer
    """

    def __init__(self, dim):
        super().__init__()
        self.gamma = nn.Parameter(torch.zeros(1, 1, 1, dim))
        self.beta = nn.Parameter(torch.zeros(1, 1, 1, dim))

    def forward(self, x):
        Gx = torch.norm(x, p=2, dim=(1, 2), keepdim=True)
        Nx = Gx / (Gx.mean(dim=-1, keepdim=True) + 1e-6)
        return self.gamma * (x * Nx) + self.beta + x


class LayerNorm(nn.Module):
    r""" LayerNorm that supports two data formats: channels_last (default) or channels_first.
    The ordering of the dimensions in the inputs. channels_last corresponds to inputs with
    shape (batch_size, height, width, channels) while channels_first corresponds to inputs
    with shape (batch_size, channels, height, width).
    """

    def __init__(self, normalized_shape, eps=1e-6, data_format="channels_last"):
        super().__init__()
        self.weight = nn.Parameter(torch.ones(normalized_shape))
        self.bias = nn.Parameter(torch.zeros(normalized_shape))
        self.eps = eps
        self.data_format = data_format
        if self.data_format not in ["channels_last", "channels_first"]:
            raise NotImplementedError
        self.normalized_shape = (normalized_shape, )

    def forward(self, x):
        if self.data_format == "channels_last":
            return F.layer_norm(x, self.normalized_shape, self.weight, self.bias, self.eps)
        elif self.data_format == "channels_first":
            u = x.mean(1, keepdim=True)
            s = (x - u).pow(2).mean(1, keepdim=True)
            x = (x - u) / torch.sqrt(s + self.eps)
            x = self.weight[:, None, None] * x + self.bias[:, None, None]
            return x


def _no_grad_trunc_normal_(tensor, mean, std, a, b):
    # Cut & paste from PyTorch official master until it's in a few official releases - RW
    # Method based on https://people.sc.fsu.edu/~jburkardt/presentations/truncated_normal.pdf
    def norm_cdf(x):
        # Computes standard normal cumulative distribution function
        return (1. + math.erf(x / math.sqrt(2.))) / 2.

    if (mean < a - 2 * std) or (mean > b + 2 * std):
        warnings.warn("mean is more than 2 std from [a, b] in nn.init.trunc_normal_. "
                      "The distribution of values may be incorrect.",
                      stacklevel=2)

    with torch.no_grad():
        # Values are generated by using a truncated uniform distribution and
        # then using the inverse CDF for the normal distribution.
        # Get upper and lower cdf values
        l = norm_cdf((a - mean) / std)
        u = norm_cdf((b - mean) / std)

        # Uniformly fill tensor with values from [l, u], then translate to
        # [2l-1, 2u-1].
        tensor.uniform_(2 * l - 1, 2 * u - 1)

        # Use inverse cdf transform for normal distribution to get truncated
        # standard normal
        tensor.erfinv_()

        # Transform to proper mean, std
        tensor.mul_(std * math.sqrt(2.))
        tensor.add_(mean)

        # Clamp to ensure it's in the proper range
        tensor.clamp_(min=a, max=b)
        return tensor


def drop_path(x, drop_prob=0., training=False, scale_by_keep=True):
    """ Drop paths (Stochastic Depth) per sample (when applied in main path of residual blocks).

    This is the same as the DropConnect impl I created for EfficientNet, etc networks, however,
    the original name is misleading as 'Drop Connect' is a different form of dropout in a separate paper...
    See discussion: https://github.com/tensorflow/tpu/issues/494#issuecomment-532968956 ... I've opted for
    changing the layer and argument names to 'drop path' rather than mix DropConnect as a layer name and use
    'survival rate' as the argument.

    """
    if drop_prob == 0. or not training:
        return x
    keep_prob = 1 - drop_prob
    shape = (x.shape[0],) + (1,) * (x.ndim - 1)  # work with diff dim tensors, not just 2D ConvNets
    random_tensor = x.new_empty(shape).bernoulli_(keep_prob)
    if keep_prob > 0.0 and scale_by_keep:
        random_tensor.div_(keep_prob)
    return x * random_tensor


class DropPath(nn.Module):
    """ Drop paths (Stochastic Depth) per sample  (when applied in main path of residual blocks).
    """

    def __init__(self, drop_prob=None, scale_by_keep=True):
        super(DropPath, self).__init__()
        self.drop_prob = drop_prob
        self.scale_by_keep = scale_by_keep

    def forward(self, x):
        return drop_path(x, self.drop_prob, self.training, self.scale_by_keep)


def trunc_normal_(tensor, mean=0., std=1., a=-2., b=2.):
    return _no_grad_trunc_normal_(tensor, mean, std, a, b)