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| import torch |
| import random |
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| def collate_data_and_cast(samples_list, mask_ratio_tuple, mask_probability, dtype, n_tokens=None, mask_generator=None): |
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| images = [] |
| indexes = [] |
| for sample in samples_list: |
| images.append(sample[0]) |
| indexes.append(sample[1]) |
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| samples_list = images |
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| n_global_crops = len(samples_list[0][0]["global_crops"]) |
| n_local_crops = len(samples_list[0][0]["local_crops"]) |
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| collated_global_crops = torch.stack([s[0]["global_crops"][i] for i in range(n_global_crops) for s in samples_list]) |
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| collated_local_crops = torch.stack([s[0]["local_crops"][i] for i in range(n_local_crops) for s in samples_list]) |
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| B = len(collated_global_crops) |
| N = n_tokens |
| n_samples_masked = int(B * mask_probability) |
| probs = torch.linspace(*mask_ratio_tuple, n_samples_masked + 1) |
| upperbound = 0 |
| masks_list = [] |
| for i in range(0, n_samples_masked): |
| prob_min = probs[i] |
| prob_max = probs[i + 1] |
| masks_list.append(torch.BoolTensor(mask_generator(int(N * random.uniform(prob_min, prob_max))))) |
| upperbound += int(N * prob_max) |
| for i in range(n_samples_masked, B): |
| masks_list.append(torch.BoolTensor(mask_generator(0))) |
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| random.shuffle(masks_list) |
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| collated_masks = torch.stack(masks_list).flatten(1) |
| mask_indices_list = collated_masks.flatten().nonzero().flatten() |
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| masks_weight = (1 / collated_masks.sum(-1).clamp(min=1.0)).unsqueeze(-1).expand_as(collated_masks)[collated_masks] |
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| return { |
| "collated_global_crops": collated_global_crops.to(dtype), |
| "collated_local_crops": collated_local_crops.to(dtype), |
| "collated_masks": collated_masks, |
| "mask_indices_list": mask_indices_list, |
| "masks_weight": masks_weight, |
| "upperbound": upperbound, |
| "n_masked_patches": torch.full((1,), fill_value=mask_indices_list.shape[0], dtype=torch.long), |
| "indexes": indexes |
| } |
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