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import pytorch_lightning as pl
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import torch
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import torch.nn as nn
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from torch.optim.lr_scheduler import ReduceLROnPlateau
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from losses import calculate_separation_loss, preservation_loss # noqa: F401
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from utils import PURE_HSV, PURE_RGB
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# class ColorTransformerModel(pl.LightningModule):
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# def __init__(self, params):
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# super().__init__()
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# self.save_hyperparameters(params)
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# # Model layers
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# self.layers = nn.Sequential(
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# nn.Linear(5, 128, bias=False),
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# nn.Linear(128, 3, bias=False),
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# nn.ReLU(),
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# nn.Linear(3, 64, bias=False),
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# nn.Linear(64, 128, bias=False),
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# nn.Linear(128, 256, bias=False),
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# nn.Linear(256, 128, bias=False),
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# nn.ReLU(),
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# nn.Linear(128, 1, bias=False),
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# )
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# def forward(self, x):
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# x = self.layers(x)
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# x = (torch.sin(x) + 1) / 2
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# return x
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# class ColorTransformerModel(pl.LightningModule):
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# def __init__(self, params):
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# super().__init__()
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# self.save_hyperparameters(params)
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# # Embedding layer to expand the input dimensions
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# self.embedding = nn.Linear(3, 128, bias=False)
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# # Transformer encoder-decoder
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# encoder = nn.TransformerEncoderLayer(
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# d_model=128, nhead=4, dim_feedforward=512, dropout=0.3
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# )
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# self.transformer_encoder = nn.TransformerEncoder(
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# encoder, num_layers=3
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# )
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# # lower dimensionality decoder
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# decoder = nn.TransformerDecoderLayer(
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# d_model=128, nhead=4, dim_feedforward=512, dropout=0.3
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# )
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# self.transformer_decoder = nn.TransformerDecoder(
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# decoder, num_layers=3
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# )
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# # Final linear layer to map back to 1D space
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# self.final_layer = nn.Linear(128, 1, bias=False)
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# def forward(self, x):
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# # Embedding the input
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# x = self.embedding(x)
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# # Adjusting the shape for the transformer
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# x = x.unsqueeze(1) # Adding a fake sequence dimension
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# # Passing through the transformer
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# x = self.transformer_encoder(x)
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# # Passing through the decoder
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# x = self.transformer_decoder(x, memory=x)
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# # Reshape back to original shape
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# x = x.squeeze(1)
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# # Final linear layer
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# x = self.final_layer(x)
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# # Apply sigmoid activation to ensure output is in (0, 1)
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# # x = torch.sigmoid(x)
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# x = (torch.sin(x) + 1) / 2
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# return x
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class ColorTransformerModel(pl.LightningModule):
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def __init__(self, params):
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super().__init__()
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self.save_hyperparameters(params)
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# self.a = nn.Sequential(
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# nn.Linear(3, 3, bias=False),
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# nn.ReLU(),
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# nn.Linear(3, 3, bias=False),
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# nn.ReLU(),
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# nn.Linear(3, 1, bias=False),
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# nn.ReLU(),
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# )
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# self.b = nn.Sequential(
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# nn.Linear(3, 3, bias=False),
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# nn.ReLU(),
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# nn.Linear(3, 3, bias=False),
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# nn.ReLU(),
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# nn.Linear(3, 1, bias=False),
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# nn.ReLU(),
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# )
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# Neural network layers
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self.network = nn.Sequential(
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nn.Linear(5, 64),
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nn.Tanh(),
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nn.Linear(64, self.hparams.width),
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nn.Tanh(),
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nn.Linear(self.hparams.width, 3),
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nn.Tanh(),
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nn.Linear(3, 1),
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)
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def forward(self, x):
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# Pass the input through the network
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# a = self.a(x)
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# b = self.b(x)
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# a = torch.sigmoid(a)
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# b = torch.sigmoid(b)
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# x = torch.cat([x, a, b], dim=-1)
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x = self.network(x)
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# Circular mapping
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# x = (torch.sin(x) + 1) / 2
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x = torch.sigmoid(x)
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return x
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def training_step(self, batch, batch_idx):
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inputs, labels = batch # x are the RGB inputs, labels are the strings
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outputs = self.forward(inputs)
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# s_loss = calculate_separation_loss(model=self)
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# preserve distance to pure R, G, B. this acts kind of like labeled data.
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s_loss = preservation_loss(
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inputs,
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outputs,
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target_inputs=PURE_RGB,
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target_outputs=PURE_HSV,
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)
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p_loss = preservation_loss(
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inputs,
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outputs,
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)
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alpha = self.hparams.alpha
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loss = p_loss + alpha * s_loss
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self.log("hp_metric", loss)
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self.log("p_loss", p_loss)
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self.log("s_loss", s_loss)
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return loss
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def configure_optimizers(self):
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optimizer = torch.optim.SGD(
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self.parameters(),
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lr=self.hparams.learning_rate,
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)
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lr_scheduler = ReduceLROnPlateau(
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optimizer, mode="min", factor=0.05, patience=5, cooldown=10, verbose=True
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)
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return {
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"optimizer": optimizer,
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"lr_scheduler": {
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"scheduler": lr_scheduler,
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"monitor": "hp_metric", # Specify the metric to monitor
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},
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}
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