| |
| import torch |
| import torch.nn as nn |
|
|
|
|
| class FourierLoss(nn.Module): |
| def __init__( |
| self, |
| use_l1_loss: bool = True, |
| num_multimodal_modalities: int = 1, |
| ) -> None: |
| """ |
| Fourier transform loss is only sound when using L1 or L2 loss to compare the frequency domains |
| between the images / their radial histograms. |
| |
| We will always set `reduction="none"` and enforce that the computation of any reductions from the |
| output of this loss be managed by the model under question. |
| """ |
| super().__init__() |
| self.loss = ( |
| nn.L1Loss(reduction="none") if use_l1_loss else nn.MSELoss(reduction="none") |
| ) |
| self.num_modalities = num_multimodal_modalities |
|
|
| def forward(self, input: torch.Tensor, target: torch.Tensor) -> torch.Tensor: |
| |
| |
| flattened_images = len(input.shape) == len(target.shape) == 3 |
| if flattened_images: |
| B, H_W, C = input.shape |
| H_W = H_W // self.num_modalities |
| four_d_shape = (B, C * self.num_modalities, int(H_W**0.5), int(H_W**0.5)) |
| input = input.view(*four_d_shape) |
| target = target.view(*four_d_shape) |
| else: |
| B, C, h, w = input.shape |
| H_W = h * w |
|
|
| if len(input.shape) != len(target.shape) != 4: |
| raise ValueError( |
| f"Invalid input shape: got {input.shape} and {target.shape}." |
| ) |
|
|
| fft_reconstructed = torch.fft.fft2(input) |
| fft_original = torch.fft.fft2(target) |
|
|
| magnitude_reconstructed = torch.abs(fft_reconstructed) |
| magnitude_original = torch.abs(fft_original) |
|
|
| loss_tensor: torch.Tensor = self.loss( |
| magnitude_reconstructed, magnitude_original |
| ) |
|
|
| if ( |
| flattened_images and not self.num_bins |
| ): |
| loss_tensor = loss_tensor.reshape(B, H_W * self.num_modalities, C) |
|
|
| return loss_tensor |
|
|
