update GNO and PointNet

ThermalSolver/model/local_gno.py

@@ -180,7 +180,6 @@ class GatingGNO(nn.Module):
                 x = blk(x, c, edge_index, edge_attr=edge_attr)
                 if plot_results:
                     x_ = self.dec(x)
-                    assert bc == x[boundary_mask]
                     plot_results_fn(x_, pos, i * _, batch=batch)
 
         return self.dec(x)

ThermalSolver/model/point_net.py

@@ -108,14 +108,14 @@ class MLP(torch.nn.Module):
         tmp_layers.append(self._output_dim)
 
         self._layers = []
-        self._batchnorm = []
+        self._LayerNorm = []
         for i in range(len(tmp_layers) - 1):
 
             self._layers.append(
                 self.spect_norm(nn.Linear(tmp_layers[i], tmp_layers[i + 1]))
             )
 
-            self._batchnorm.append(nn.LazyBatchNorm1d())
+            self._LayerNorm.append(nn.LazyLayerNorm())
 
         if isinstance(func, list):
             self._functions = func
@@ -124,7 +124,7 @@ class MLP(torch.nn.Module):
 
         unique_list = []
         for layer, func, bnorm in zip(
-            self._layers[:-1], self._functions, self._batchnorm
+            self._layers[:-1], self._functions, self._LayerNorm
         ):
 
             unique_list.append(layer)
@@ -208,7 +208,7 @@ class TNet(nn.Module):
         )
 
         self._function = function()
-        self._bn1 = nn.LazyBatchNorm1d()
+        self._bn1 = nn.LazyLayerNorm()
 
     def forward(self, X):
         """Forward pass for T-Net
@@ -299,9 +299,9 @@ class PointNet(nn.Module):
             self._tnet_feature = TNet(input_dim=64)
 
         self._function = function()
-        self._bn1 = nn.LazyBatchNorm1d()
-        self._bn2 = nn.LazyBatchNorm1d()
-        self._bn3 = nn.LazyBatchNorm1d()
+        self._bn1 = nn.LazyLayerNorm()
+        self._bn2 = nn.LazyLayerNorm()
+        self._bn3 = nn.LazyLayerNorm()
 
     def concat(self, embedding, input_):
         """Returns concatenation of global and local features for Point-Net
@@ -370,205 +370,3 @@ class PointNet(nn.Module):
         X = self._mlp4(X)
 
         return X
-
-
-class ConvTNet(nn.Module):
-    """T-Net base class. Implementation of T-Network with convolutional layers.
-
-    Reference: Ali Kashefi et al. https://arxiv.org/abs/2208.13434
-    """
-
-    def __init__(self, input_dim):
-        """T-Net block constructor
-
-        :param input_dim: input dimension of point cloud
-        :type input_dim: int
-        """
-        super().__init__()
-
-        function = nn.Tanh
-        self._function = function()
-
-        self._block1 = nn.Sequential(
-            nn.Conv1d(input_dim, 64, 1),
-            nn.BatchNorm1d(64),
-            self._function,
-            nn.Conv1d(64, 128, 1),
-            nn.BatchNorm1d(128),
-            self._function,
-            nn.Conv1d(128, 1024, 1),
-            nn.BatchNorm1d(1024),
-            self._function,
-        )
-
-        self._block2 = MLP(
-            input_dim=1024,
-            output_dim=input_dim * input_dim,
-            layers=[512, 256],
-            func=function,
-            batch_norm=True,
-        )
-
-    def forward(self, X):
-        """Forward pass for T-Net
-
-        :param X: input tensor, shape [batch, $input_{dim}$, N]
-        with batch the batch size, N number of points and $input_{dim}$
-        the input dimension of the point cloud.
-        :type X: torch.tensor
-        :return: output affine matrix transformation, shape
-        [batch, $input_{dim} \times input_{dim}$] with batch
-        the batch size and $input_{dim}$ the input dimension
-        of the point cloud.
-        :rtype: torch.tensor
-        """
-
-        batch, input_dim = X.shape[0], X.shape[1]
-
-        # encoding using first MLP
-        X = self._block1(X)
-
-        # applying symmetric function to aggregate information (using max as default)
-        X, _ = torch.max(X, dim=-1)
-
-        # decoding using third MLP
-        X = self._block2(X)
-
-        return X.reshape(batch, input_dim, input_dim)
-
-
-class ConvPointNet(nn.Module):
-    """Point-Net base class. Implementation of Point Network for segmentation.
-
-    Reference: Ali Kashefi et al. https://arxiv.org/abs/2208.13434
-    """
-
-    def __init__(self, input_dim, output_dim, tnet=False):
-        """Point-Net block constructor
-
-        :param input_dim: input dimension of point cloud
-        :type input_dim: int
-        :param output_dim: output dimension of point cloud
-        :type output_dim: int
-        :param tnet: apply T-Net transformation, defaults to False
-        :type tnet: bool, optional
-        """
-        super().__init__()
-
-        self._function = nn.Tanh()
-        self._use_tnet = tnet
-
-        self._block1 = nn.Sequential(
-            nn.Conv1d(input_dim, 64, 1),
-            nn.BatchNorm1d(64),
-            self._function,
-            nn.Conv1d(64, 64, 1),
-            nn.BatchNorm1d(64),
-            self._function,
-        )
-
-        self._block2 = nn.Sequential(
-            nn.Conv1d(64, 64, 1),
-            nn.BatchNorm1d(64),
-            self._function,
-            nn.Conv1d(64, 128, 1),
-            nn.BatchNorm1d(128),
-            self._function,
-            nn.Conv1d(128, 1024, 1),
-            nn.BatchNorm1d(1024),
-            self._function,
-        )
-
-        self._block3 = nn.Sequential(
-            nn.Conv1d(1088, 512, 1),
-            nn.BatchNorm1d(512),
-            self._function,
-            nn.Conv1d(512, 256, 1),
-            nn.BatchNorm1d(256),
-            self._function,
-            nn.Conv1d(256, 128, 1),
-            nn.BatchNorm1d(128),
-            self._function,
-        )
-
-        self._block4 = nn.Conv1d(128, output_dim, 1)
-
-        if self._use_tnet:
-            self._tnet_transform = ConvTNet(input_dim=input_dim)
-            self._tnet_feature = ConvTNet(input_dim=64)
-
-    def concat(self, embedding, input_):
-        """
-        Returns concatenation of global and local features for Point-Net
-
-        :param embedding: global features of Point-Net, shape [batch, $input_{dim}$]
-        with batch the batch size and $input_{dim}$ the input dimension
-        of the point cloud.
-        :type embedding: torch.tensor
-        :param input_: local features of Point-Net, shape [batch, N, $input_{dim}$]
-        with batch the batch size, N number of points and $input_{dim}$
-        the input dimension of the point cloud.
-        :type input_: torch.tensor
-        :return: concatenation vector, shape [batch, N, $input_{dim}$]
-        with batch the batch size, N number of points and $input_{dim}$
-        :rtype: torch.tensor
-        """
-        n_points = input_.shape[-1]
-        embedding = embedding.unsqueeze(2).repeat(1, 1, n_points)
-        return torch.cat([embedding, input_], dim=1)
-
-    def forward(self, X):
-        """Forward pass for Point-Net
-
-        :param X: input tensor, shape [batch, N, $input_{dim}$]
-        with batch the batch size, N number of points and $input_{dim}$
-        the input dimension of the point cloud.
-        :type X: torch.tensor
-        :return: segmentation vector, shape [batch, N, $output_{dim}$]
-        with batch the batch size, N number of points and $output_{dim}$
-        the output dimension of the point cloud.
-        :rtype: torch.tensor
-        """
-
-        # permuting indeces
-        X = X.permute(0, 2, 1)
-
-        # using transform tnet if needed
-        if self._use_tnet:
-            transform = self._tnet_transform(X)
-            X = X.transpose(2, 1)
-            X = torch.matmul(X, transform)
-            X = X.transpose(2, 1)
-
-        # encoding using first MLP
-        X = self._block1(X)
-
-        # using transform tnet if needed
-        if self._use_tnet:
-            transform = self._tnet_feature(X)
-            X = X.transpose(2, 1)
-            X = torch.matmul(X, transform)
-            X = X.transpose(2, 1)
-
-        # saving latent representation for later concatanation
-        latent = X
-
-        # encoding using second MLP
-        X = self._block2(X)
-
-        # applying symmetric function to aggregate information (using max as default)
-        X, _ = torch.max(X, dim=-1)
-
-        # concatenating with latent vector
-        X = self.concat(X, latent)
-
-        # decoding using third MLP
-        X = self._block3(X)
-
-        # decoding using fourth MLP
-        X = self._block4(X)
-
-        # permuting indeces
-        X = X.permute(0, 2, 1)
-
-        return X