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import functools
import torch
import torch.nn as nn
from .base_function import LayerNorm2d, ADAINHourglass, FineEncoder, FineDecoder

def convert_flow_to_deformation(flow):
    r"""convert flow fields to deformations.

    Args:
        flow (tensor): Flow field obtained by the model
    Returns:
        deformation (tensor): The deformation used for warpping
    """
    b,c,h,w = flow.shape
    flow_norm = 2 * torch.cat([flow[:,:1,...]/(w-1),flow[:,1:,...]/(h-1)], 1)
    grid = make_coordinate_grid(flow)
    deformation = grid + flow_norm.permute(0,2,3,1)
    return deformation

def make_coordinate_grid(flow):
    r"""obtain coordinate grid with the same size as the flow filed.

    Args:
        flow (tensor): Flow field obtained by the model
    Returns:
        grid (tensor): The grid with the same size as the input flow
    """    
    b,c,h,w = flow.shape

    x = torch.arange(w).to(flow)
    y = torch.arange(h).to(flow)

    x = (2 * (x / (w - 1)) - 1)
    y = (2 * (y / (h - 1)) - 1)

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

    meshed = torch.cat([xx.unsqueeze_(2), yy.unsqueeze_(2)], 2)
    meshed = meshed.expand(b, -1, -1, -1)
    return meshed    

    
def warp_image(source_image, deformation):
    r"""warp the input image according to the deformation

    Args:
        source_image (tensor): source images to be warpped
        deformation (tensor): deformations used to warp the images; value in range (-1, 1)
    Returns:
        output (tensor): the warpped images
    """ 
    _, h_old, w_old, _ = deformation.shape
    _, _, h, w = source_image.shape
    if h_old != h or w_old != w:
        deformation = deformation.permute(0, 3, 1, 2)
        deformation = torch.nn.functional.interpolate(deformation, size=(h, w), mode='bilinear')
        deformation = deformation.permute(0, 2, 3, 1)
    return torch.nn.functional.grid_sample(source_image, deformation) 


class FaceGenerator(nn.Module):
    def __init__(
        self, 
        mapping_net, 
        warpping_net, 
        editing_net, 
        common
        ):  
        super(FaceGenerator, self).__init__()
        self.mapping_net = MappingNet(**mapping_net)
        self.warpping_net = WarpingNet(**warpping_net, **common)
        self.editing_net = EditingNet(**editing_net, **common)
 
    def forward(
        self, 
        input_image, 
        driving_source, 
        stage=None
        ):
        if stage == 'warp':
            descriptor = self.mapping_net(driving_source)
            output = self.warpping_net(input_image, descriptor)
        else:
            descriptor = self.mapping_net(driving_source)
            output = self.warpping_net(input_image, descriptor)
            output['fake_image'] = self.editing_net(input_image, output['warp_image'], descriptor)
        return output

class MappingNet(nn.Module):
    def __init__(self, coeff_nc, descriptor_nc, layer):
        super( MappingNet, self).__init__()

        self.layer = layer
        nonlinearity = nn.LeakyReLU(0.1)

        self.first = nn.Sequential(
            torch.nn.Conv1d(coeff_nc, descriptor_nc, kernel_size=7, padding=0, bias=True))

        for i in range(layer):
            net = nn.Sequential(nonlinearity,
                torch.nn.Conv1d(descriptor_nc, descriptor_nc, kernel_size=3, padding=0, dilation=3))
            setattr(self, 'encoder' + str(i), net)   

        self.pooling = nn.AdaptiveAvgPool1d(1)
        self.output_nc = descriptor_nc

    def forward(self, input_3dmm):
        out = self.first(input_3dmm)
        for i in range(self.layer):
            model = getattr(self, 'encoder' + str(i))
            out = model(out) + out[:,:,3:-3]
        out = self.pooling(out)
        return out   

class WarpingNet(nn.Module):
    def __init__(
        self, 
        image_nc, 
        descriptor_nc, 
        base_nc, 
        max_nc, 
        encoder_layer, 
        decoder_layer, 
        use_spect
        ):
        super( WarpingNet, self).__init__()

        nonlinearity = nn.LeakyReLU(0.1)
        norm_layer = functools.partial(LayerNorm2d, affine=True) 
        kwargs = {'nonlinearity':nonlinearity, 'use_spect':use_spect}

        self.descriptor_nc = descriptor_nc 
        self.hourglass = ADAINHourglass(image_nc, self.descriptor_nc, base_nc,
                                       max_nc, encoder_layer, decoder_layer, **kwargs)

        self.flow_out = nn.Sequential(norm_layer(self.hourglass.output_nc), 
                                      nonlinearity,
                                      nn.Conv2d(self.hourglass.output_nc, 2, kernel_size=7, stride=1, padding=3))

        self.pool = nn.AdaptiveAvgPool2d(1)

    def forward(self, input_image, descriptor):
        final_output={}
        output = self.hourglass(input_image, descriptor)
        final_output['flow_field'] = self.flow_out(output)

        deformation = convert_flow_to_deformation(final_output['flow_field'])
        final_output['warp_image'] = warp_image(input_image, deformation)
        return final_output


class EditingNet(nn.Module):
    def __init__(
        self, 
        image_nc, 
        descriptor_nc, 
        layer, 
        base_nc, 
        max_nc, 
        num_res_blocks, 
        use_spect):  
        super(EditingNet, self).__init__()

        nonlinearity = nn.LeakyReLU(0.1)
        norm_layer = functools.partial(LayerNorm2d, affine=True) 
        kwargs = {'norm_layer':norm_layer, 'nonlinearity':nonlinearity, 'use_spect':use_spect}
        self.descriptor_nc = descriptor_nc

        # encoder part
        self.encoder = FineEncoder(image_nc*2, base_nc, max_nc, layer, **kwargs)
        self.decoder = FineDecoder(image_nc, self.descriptor_nc, base_nc, max_nc, layer, num_res_blocks, **kwargs)

    def forward(self, input_image, warp_image, descriptor):
        x = torch.cat([input_image, warp_image], 1)
        x = self.encoder(x)
        gen_image = self.decoder(x, descriptor)
        return gen_image