""" Modified by Nikita Selin (OPHoperHPO)[https://github.com/OPHoperHPO]. Source url: https://github.com/MarcoForte/FBA_Matting License: MIT License """ import torch import torch.nn as nn import carvekit.ml.arch.fba_matting.resnet_GN_WS as resnet_GN_WS import carvekit.ml.arch.fba_matting.layers_WS as L import carvekit.ml.arch.fba_matting.resnet_bn as resnet_bn from functools import partial class FBA(nn.Module): def __init__(self, encoder: str): super(FBA, self).__init__() self.encoder = build_encoder(arch=encoder) self.decoder = fba_decoder(batch_norm=True if "BN" in encoder else False) def forward(self, image, two_chan_trimap, image_n, trimap_transformed): resnet_input = torch.cat((image_n, trimap_transformed, two_chan_trimap), 1) conv_out, indices = self.encoder(resnet_input, return_feature_maps=True) return self.decoder(conv_out, image, indices, two_chan_trimap) class ResnetDilatedBN(nn.Module): def __init__(self, orig_resnet, dilate_scale=8): super(ResnetDilatedBN, self).__init__() if dilate_scale == 8: orig_resnet.layer3.apply(partial(self._nostride_dilate, dilate=2)) orig_resnet.layer4.apply(partial(self._nostride_dilate, dilate=4)) elif dilate_scale == 16: orig_resnet.layer4.apply(partial(self._nostride_dilate, dilate=2)) # take pretrained resnet, except AvgPool and FC self.conv1 = orig_resnet.conv1 self.bn1 = orig_resnet.bn1 self.relu1 = orig_resnet.relu1 self.conv2 = orig_resnet.conv2 self.bn2 = orig_resnet.bn2 self.relu2 = orig_resnet.relu2 self.conv3 = orig_resnet.conv3 self.bn3 = orig_resnet.bn3 self.relu3 = orig_resnet.relu3 self.maxpool = orig_resnet.maxpool self.layer1 = orig_resnet.layer1 self.layer2 = orig_resnet.layer2 self.layer3 = orig_resnet.layer3 self.layer4 = orig_resnet.layer4 def _nostride_dilate(self, m, dilate): classname = m.__class__.__name__ if classname.find("Conv") != -1: # the convolution with stride if m.stride == (2, 2): m.stride = (1, 1) if m.kernel_size == (3, 3): m.dilation = (dilate // 2, dilate // 2) m.padding = (dilate // 2, dilate // 2) # other convoluions else: if m.kernel_size == (3, 3): m.dilation = (dilate, dilate) m.padding = (dilate, dilate) def forward(self, x, return_feature_maps=False): conv_out = [x] x = self.relu1(self.bn1(self.conv1(x))) x = self.relu2(self.bn2(self.conv2(x))) x = self.relu3(self.bn3(self.conv3(x))) conv_out.append(x) x, indices = self.maxpool(x) x = self.layer1(x) conv_out.append(x) x = self.layer2(x) conv_out.append(x) x = self.layer3(x) conv_out.append(x) x = self.layer4(x) conv_out.append(x) if return_feature_maps: return conv_out, indices return [x] class Resnet(nn.Module): def __init__(self, orig_resnet): super(Resnet, self).__init__() # take pretrained resnet, except AvgPool and FC self.conv1 = orig_resnet.conv1 self.bn1 = orig_resnet.bn1 self.relu1 = orig_resnet.relu1 self.conv2 = orig_resnet.conv2 self.bn2 = orig_resnet.bn2 self.relu2 = orig_resnet.relu2 self.conv3 = orig_resnet.conv3 self.bn3 = orig_resnet.bn3 self.relu3 = orig_resnet.relu3 self.maxpool = orig_resnet.maxpool self.layer1 = orig_resnet.layer1 self.layer2 = orig_resnet.layer2 self.layer3 = orig_resnet.layer3 self.layer4 = orig_resnet.layer4 def forward(self, x, return_feature_maps=False): conv_out = [] x = self.relu1(self.bn1(self.conv1(x))) x = self.relu2(self.bn2(self.conv2(x))) x = self.relu3(self.bn3(self.conv3(x))) conv_out.append(x) x, indices = self.maxpool(x) x = self.layer1(x) conv_out.append(x) x = self.layer2(x) conv_out.append(x) x = self.layer3(x) conv_out.append(x) x = self.layer4(x) conv_out.append(x) if return_feature_maps: return conv_out return [x] class ResnetDilated(nn.Module): def __init__(self, orig_resnet, dilate_scale=8): super(ResnetDilated, self).__init__() if dilate_scale == 8: orig_resnet.layer3.apply(partial(self._nostride_dilate, dilate=2)) orig_resnet.layer4.apply(partial(self._nostride_dilate, dilate=4)) elif dilate_scale == 16: orig_resnet.layer4.apply(partial(self._nostride_dilate, dilate=2)) # take pretrained resnet, except AvgPool and FC self.conv1 = orig_resnet.conv1 self.bn1 = orig_resnet.bn1 self.relu = orig_resnet.relu self.maxpool = orig_resnet.maxpool self.layer1 = orig_resnet.layer1 self.layer2 = orig_resnet.layer2 self.layer3 = orig_resnet.layer3 self.layer4 = orig_resnet.layer4 def _nostride_dilate(self, m, dilate): classname = m.__class__.__name__ if classname.find("Conv") != -1: # the convolution with stride if m.stride == (2, 2): m.stride = (1, 1) if m.kernel_size == (3, 3): m.dilation = (dilate // 2, dilate // 2) m.padding = (dilate // 2, dilate // 2) # other convoluions else: if m.kernel_size == (3, 3): m.dilation = (dilate, dilate) m.padding = (dilate, dilate) def forward(self, x, return_feature_maps=False): conv_out = [x] x = self.relu(self.bn1(self.conv1(x))) conv_out.append(x) x, indices = self.maxpool(x) x = self.layer1(x) conv_out.append(x) x = self.layer2(x) conv_out.append(x) x = self.layer3(x) conv_out.append(x) x = self.layer4(x) conv_out.append(x) if return_feature_maps: return conv_out, indices return [x] def norm(dim, bn=False): if bn is False: return nn.GroupNorm(32, dim) else: return nn.BatchNorm2d(dim) def fba_fusion(alpha, img, F, B): F = alpha * img + (1 - alpha**2) * F - alpha * (1 - alpha) * B B = (1 - alpha) * img + (2 * alpha - alpha**2) * B - alpha * (1 - alpha) * F F = torch.clamp(F, 0, 1) B = torch.clamp(B, 0, 1) la = 0.1 alpha = (alpha * la + torch.sum((img - B) * (F - B), 1, keepdim=True)) / ( torch.sum((F - B) * (F - B), 1, keepdim=True) + la ) alpha = torch.clamp(alpha, 0, 1) return alpha, F, B class fba_decoder(nn.Module): def __init__(self, batch_norm=False): super(fba_decoder, self).__init__() pool_scales = (1, 2, 3, 6) self.batch_norm = batch_norm self.ppm = [] for scale in pool_scales: self.ppm.append( nn.Sequential( nn.AdaptiveAvgPool2d(scale), L.Conv2d(2048, 256, kernel_size=1, bias=True), norm(256, self.batch_norm), nn.LeakyReLU(), ) ) self.ppm = nn.ModuleList(self.ppm) self.conv_up1 = nn.Sequential( L.Conv2d( 2048 + len(pool_scales) * 256, 256, kernel_size=3, padding=1, bias=True ), norm(256, self.batch_norm), nn.LeakyReLU(), L.Conv2d(256, 256, kernel_size=3, padding=1), norm(256, self.batch_norm), nn.LeakyReLU(), ) self.conv_up2 = nn.Sequential( L.Conv2d(256 + 256, 256, kernel_size=3, padding=1, bias=True), norm(256, self.batch_norm), nn.LeakyReLU(), ) if self.batch_norm: d_up3 = 128 else: d_up3 = 64 self.conv_up3 = nn.Sequential( L.Conv2d(256 + d_up3, 64, kernel_size=3, padding=1, bias=True), norm(64, self.batch_norm), nn.LeakyReLU(), ) self.unpool = nn.MaxUnpool2d(2, stride=2) self.conv_up4 = nn.Sequential( nn.Conv2d(64 + 3 + 3 + 2, 32, kernel_size=3, padding=1, bias=True), nn.LeakyReLU(), nn.Conv2d(32, 16, kernel_size=3, padding=1, bias=True), nn.LeakyReLU(), nn.Conv2d(16, 7, kernel_size=1, padding=0, bias=True), ) def forward(self, conv_out, img, indices, two_chan_trimap): conv5 = conv_out[-1] input_size = conv5.size() ppm_out = [conv5] for pool_scale in self.ppm: ppm_out.append( nn.functional.interpolate( pool_scale(conv5), (input_size[2], input_size[3]), mode="bilinear", align_corners=False, ) ) ppm_out = torch.cat(ppm_out, 1) x = self.conv_up1(ppm_out) x = torch.nn.functional.interpolate( x, scale_factor=2, mode="bilinear", align_corners=False ) x = torch.cat((x, conv_out[-4]), 1) x = self.conv_up2(x) x = torch.nn.functional.interpolate( x, scale_factor=2, mode="bilinear", align_corners=False ) x = torch.cat((x, conv_out[-5]), 1) x = self.conv_up3(x) x = torch.nn.functional.interpolate( x, scale_factor=2, mode="bilinear", align_corners=False ) x = torch.cat((x, conv_out[-6][:, :3], img, two_chan_trimap), 1) output = self.conv_up4(x) alpha = torch.clamp(output[:, 0][:, None], 0, 1) F = torch.sigmoid(output[:, 1:4]) B = torch.sigmoid(output[:, 4:7]) # FBA Fusion alpha, F, B = fba_fusion(alpha, img, F, B) output = torch.cat((alpha, F, B), 1) return output def build_encoder(arch="resnet50_GN"): if arch == "resnet50_GN_WS": orig_resnet = resnet_GN_WS.__dict__["l_resnet50"]() net_encoder = ResnetDilated(orig_resnet, dilate_scale=8) elif arch == "resnet50_BN": orig_resnet = resnet_bn.__dict__["l_resnet50"]() net_encoder = ResnetDilatedBN(orig_resnet, dilate_scale=8) else: raise ValueError("Architecture undefined!") num_channels = 3 + 6 + 2 if num_channels > 3: net_encoder_sd = net_encoder.state_dict() conv1_weights = net_encoder_sd["conv1.weight"] c_out, c_in, h, w = conv1_weights.size() conv1_mod = torch.zeros(c_out, num_channels, h, w) conv1_mod[:, :3, :, :] = conv1_weights conv1 = net_encoder.conv1 conv1.in_channels = num_channels conv1.weight = torch.nn.Parameter(conv1_mod) net_encoder.conv1 = conv1 net_encoder_sd["conv1.weight"] = conv1_mod net_encoder.load_state_dict(net_encoder_sd) return net_encoder