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from lib.net.FBNet import define_G |
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from lib.net.net_util import init_net, VGGLoss |
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from lib.net.HGFilters import * |
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from lib.net.BasePIFuNet import BasePIFuNet |
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import torch |
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import torch.nn as nn |
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class NormalNet(BasePIFuNet): |
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''' |
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HG PIFu network uses Hourglass stacks as the image filter. |
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It does the following: |
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1. Compute image feature stacks and store it in self.im_feat_list |
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self.im_feat_list[-1] is the last stack (output stack) |
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2. Calculate calibration |
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3. If training, it index on every intermediate stacks, |
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If testing, it index on the last stack. |
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4. Classification. |
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5. During training, error is calculated on all stacks. |
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''' |
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def __init__(self, cfg, error_term=nn.SmoothL1Loss()): |
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super(NormalNet, self).__init__(error_term=error_term) |
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self.l1_loss = nn.SmoothL1Loss() |
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self.opt = cfg.net |
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self.training=False |
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if self.training: |
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self.vgg_loss = [VGGLoss()] |
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self.in_nmlF = [ |
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item[0] for item in self.opt.in_nml |
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if '_F' in item[0] or item[0] == 'image' |
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] |
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self.in_nmlB = [ |
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item[0] for item in self.opt.in_nml |
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if '_B' in item[0] or item[0] == 'image' |
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] |
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self.in_nmlF_dim = sum([ |
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item[1] for item in self.opt.in_nml |
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if '_F' in item[0] or item[0] == 'image' |
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]) |
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self.in_nmlB_dim = sum([ |
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item[1] for item in self.opt.in_nml |
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if '_B' in item[0] or item[0] == 'image' |
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]) |
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self.netF = define_G(self.in_nmlF_dim, 3, 64, "global", 4, 9, 1, 3, |
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"instance") |
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self.netB = define_G(self.in_nmlB_dim, 3, 64, "global", 4, 9, 1, 3, |
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"instance") |
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init_net(self) |
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def forward(self, in_tensor): |
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inF_list = [] |
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inB_list = [] |
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for name in self.in_nmlF: |
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inF_list.append(in_tensor[name]) |
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for name in self.in_nmlB: |
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inB_list.append(in_tensor[name]) |
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nmlF = self.netF(torch.cat(inF_list, dim=1)) |
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nmlB = self.netB(torch.cat(inB_list, dim=1)) |
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nmlF = nmlF / torch.norm(nmlF, dim=1, keepdim=True) |
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nmlB = nmlB / torch.norm(nmlB, dim=1, keepdim=True) |
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mask = (in_tensor['image'].abs().sum(dim=1, keepdim=True) != |
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0.0).detach().float() |
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nmlF = nmlF * mask |
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nmlB = nmlB * mask |
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return nmlF, nmlB |
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def get_norm_error(self, prd_F, prd_B, tgt): |
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"""calculate normal loss |
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Args: |
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pred (torch.tensor): [B, 6, 512, 512] |
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tagt (torch.tensor): [B, 6, 512, 512] |
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""" |
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tgt_F, tgt_B = tgt['normal_F'], tgt['normal_B'] |
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l1_F_loss = self.l1_loss(prd_F, tgt_F) |
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l1_B_loss = self.l1_loss(prd_B, tgt_B) |
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with torch.no_grad(): |
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vgg_F_loss = self.vgg_loss[0](prd_F, tgt_F) |
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vgg_B_loss = self.vgg_loss[0](prd_B, tgt_B) |
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total_loss = [ |
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5.0 * l1_F_loss + vgg_F_loss, 5.0 * l1_B_loss + vgg_B_loss |
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] |
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return total_loss |
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