| import torch |
| import torch.nn as nn |
| import torch.nn.functional as F |
| from torch_scatter import scatter_mean, scatter_max |
| from .unet import UNet |
| from .resnet_block import ResnetBlockFC |
| from .PointEMB import PointEmbed |
| import numpy as np |
|
|
| class ParPoint_Encoder(nn.Module): |
| ''' PointNet-based encoder network with ResNet blocks for each point. |
| Number of input points are fixed. |
| |
| Args: |
| c_dim (int): dimension of latent code c |
| dim (int): input points dimension |
| hidden_dim (int): hidden dimension of the network |
| scatter_type (str): feature aggregation when doing local pooling |
| unet (bool): weather to use U-Net |
| unet_kwargs (str): U-Net parameters |
| plane_resolution (int): defined resolution for plane feature |
| plane_type (str): feature type, 'xz' - 1-plane, ['xz', 'xy', 'yz'] - 3-plane, ['grid'] - 3D grid volume |
| padding (float): conventional padding paramter of ONet for unit cube, so [-0.5, 0.5] -> [-0.55, 0.55] |
| n_blocks (int): number of blocks ResNetBlockFC layers |
| ''' |
|
|
| def __init__(self, c_dim=128, dim=3, hidden_dim=128, scatter_type='max', unet_kwargs=None, |
| plane_resolution=None, plane_type=['xz', 'xy', 'yz'], padding=0.1, n_blocks=5): |
| super().__init__() |
| self.c_dim = c_dim |
|
|
| self.fc_pos = nn.Linear(dim, 2 * hidden_dim) |
| self.blocks = nn.ModuleList([ |
| ResnetBlockFC(2 * hidden_dim, hidden_dim) for i in range(n_blocks) |
| ]) |
| self.fc_c = nn.Linear(hidden_dim, c_dim) |
|
|
| self.actvn = nn.ReLU() |
| self.hidden_dim = hidden_dim |
|
|
| self.unet = UNet(unet_kwargs['output_dim'], in_channels=c_dim, **unet_kwargs) |
|
|
| self.reso_plane = plane_resolution |
| self.plane_type = plane_type |
| self.padding = padding |
|
|
| if scatter_type == 'max': |
| self.scatter = scatter_max |
| elif scatter_type == 'mean': |
| self.scatter = scatter_mean |
|
|
| |
| |
| def forward(self, p,point_emb): |
| batch_size, T, D = p.size() |
| |
| |
| coord = {} |
| index = {} |
| if 'xz' in self.plane_type: |
| coord['xz'] = self.normalize_coordinate(p.clone(), plane='xz', padding=self.padding) |
| index['xz'] = self.coordinate2index(coord['xz'], self.reso_plane) |
| if 'xy' in self.plane_type: |
| coord['xy'] = self.normalize_coordinate(p.clone(), plane='xy', padding=self.padding) |
| index['xy'] = self.coordinate2index(coord['xy'], self.reso_plane) |
| if 'yz' in self.plane_type: |
| coord['yz'] = self.normalize_coordinate(p.clone(), plane='yz', padding=self.padding) |
| index['yz'] = self.coordinate2index(coord['yz'], self.reso_plane) |
| net = self.fc_pos(point_emb) |
|
|
| net = self.blocks[0](net) |
| for block in self.blocks[1:]: |
| pooled = self.pool_local(coord, index, net) |
| net = torch.cat([net, pooled], dim=2) |
| net = block(net) |
|
|
| c = self.fc_c(net) |
| |
|
|
| fea = {} |
| |
| if 'xz' in self.plane_type: |
| fea['xz'] = self.generate_plane_features(p, c, |
| plane='xz') |
| if 'xy' in self.plane_type: |
| fea['xy'] = self.generate_plane_features(p, c, plane='xy') |
| if 'yz' in self.plane_type: |
| fea['yz'] = self.generate_plane_features(p, c, plane='yz') |
| cat_feature = torch.cat([fea['xz'], fea['xy'], fea['yz']], |
| dim=2) |
| |
| plane_feat=self.unet(cat_feature) |
|
|
| return plane_feat |
|
|
|
|
| def normalize_coordinate(self, p, padding=0.1, plane='xz'): |
| ''' Normalize coordinate to [0, 1] for unit cube experiments |
| |
| Args: |
| p (tensor): point |
| padding (float): conventional padding paramter of ONet for unit cube, so [-0.5, 0.5] -> [-0.55, 0.55] |
| plane (str): plane feature type, ['xz', 'xy', 'yz'] |
| ''' |
| if plane == 'xz': |
| xy = p[:, :, [0, 2]] |
| elif plane == 'xy': |
| xy = p[:, :, [0, 1]] |
| else: |
| xy = p[:, :, [1, 2]] |
| |
| xy=xy/2 |
| xy_new = xy / (1 + padding + 10e-6) |
| xy_new = xy_new + 0.5 |
| |
|
|
| |
| if xy_new.max() >= 1: |
| xy_new[xy_new >= 1] = 1 - 10e-6 |
| if xy_new.min() < 0: |
| xy_new[xy_new < 0] = 0.0 |
| return xy_new |
|
|
| def coordinate2index(self, x, reso): |
| ''' Normalize coordinate to [0, 1] for unit cube experiments. |
| Corresponds to our 3D model |
| |
| Args: |
| x (tensor): coordinate |
| reso (int): defined resolution |
| coord_type (str): coordinate type |
| ''' |
| x = (x * reso).long() |
| index = x[:, :, 0] + reso * x[:, :, 1] |
| index = index[:, None, :] |
| return index |
|
|
| |
| |
| def pool_local(self, xy, index, c): |
| bs, fea_dim = c.size(0), c.size(2) |
| keys = xy.keys() |
|
|
| c_out = 0 |
| for key in keys: |
| |
| fea = self.scatter(c.permute(0, 2, 1), index[key], dim_size=self.reso_plane ** 2) |
| if self.scatter == scatter_max: |
| fea = fea[0] |
| |
| fea = fea.gather(dim=2, index=index[key].expand(-1, fea_dim, -1)) |
| c_out += fea |
| return c_out.permute(0, 2, 1) |
|
|
| def generate_plane_features(self, p, c, plane='xz'): |
| |
| xy = self.normalize_coordinate(p.clone(), plane=plane, padding=self.padding) |
| index = self.coordinate2index(xy, self.reso_plane) |
|
|
| |
| fea_plane = c.new_zeros(p.size(0), self.c_dim, self.reso_plane ** 2) |
| c = c.permute(0, 2, 1) |
| fea_plane = scatter_mean(c, index, out=fea_plane) |
| fea_plane = fea_plane.reshape(p.size(0), self.c_dim, self.reso_plane, |
| self.reso_plane) |
| |
|
|
| return fea_plane |