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""" |
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PyTorch utilities: Utilities related to PyTorch |
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""" |
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from typing import List, Optional, Tuple, Union |
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from . import logging |
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from .import_utils import is_torch_available, is_torch_version |
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if is_torch_available(): |
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import torch |
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from torch.fft import fftn, fftshift, ifftn, ifftshift |
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logger = logging.get_logger(__name__) |
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try: |
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from torch._dynamo import allow_in_graph as maybe_allow_in_graph |
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except (ImportError, ModuleNotFoundError): |
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def maybe_allow_in_graph(cls): |
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return cls |
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def randn_tensor( |
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shape: Union[Tuple, List], |
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generator: Optional[Union[List["torch.Generator"], "torch.Generator"]] = None, |
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device: Optional["torch.device"] = None, |
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dtype: Optional["torch.dtype"] = None, |
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layout: Optional["torch.layout"] = None, |
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): |
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"""A helper function to create random tensors on the desired `device` with the desired `dtype`. When |
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passing a list of generators, you can seed each batch size individually. If CPU generators are passed, the tensor |
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is always created on the CPU. |
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""" |
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rand_device = device |
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batch_size = shape[0] |
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layout = layout or torch.strided |
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device = device or torch.device("cpu") |
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if generator is not None: |
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gen_device_type = generator.device.type if not isinstance(generator, list) else generator[0].device.type |
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if gen_device_type != device.type and gen_device_type == "cpu": |
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rand_device = "cpu" |
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if device != "mps": |
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logger.info( |
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f"The passed generator was created on 'cpu' even though a tensor on {device} was expected." |
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f" Tensors will be created on 'cpu' and then moved to {device}. Note that one can probably" |
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f" slighly speed up this function by passing a generator that was created on the {device} device." |
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) |
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elif gen_device_type != device.type and gen_device_type == "cuda": |
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raise ValueError(f"Cannot generate a {device} tensor from a generator of type {gen_device_type}.") |
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if isinstance(generator, list) and len(generator) == 1: |
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generator = generator[0] |
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if isinstance(generator, list): |
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shape = (1,) + shape[1:] |
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latents = [ |
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torch.randn(shape, generator=generator[i], device=rand_device, dtype=dtype, layout=layout) |
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for i in range(batch_size) |
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] |
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latents = torch.cat(latents, dim=0).to(device) |
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else: |
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latents = torch.randn(shape, generator=generator, device=rand_device, dtype=dtype, layout=layout).to(device) |
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return latents |
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def is_compiled_module(module) -> bool: |
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"""Check whether the module was compiled with torch.compile()""" |
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if is_torch_version("<", "2.0.0") or not hasattr(torch, "_dynamo"): |
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return False |
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return isinstance(module, torch._dynamo.eval_frame.OptimizedModule) |
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def fourier_filter(x_in: "torch.Tensor", threshold: int, scale: int) -> "torch.Tensor": |
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"""Fourier filter as introduced in FreeU (https://arxiv.org/abs/2309.11497). |
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This version of the method comes from here: |
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https://github.com/huggingface/diffusers/pull/5164#issuecomment-1732638706 |
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""" |
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x = x_in |
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B, C, H, W = x.shape |
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if (W & (W - 1)) != 0 or (H & (H - 1)) != 0: |
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x = x.to(dtype=torch.float32) |
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x_freq = fftn(x, dim=(-2, -1)) |
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x_freq = fftshift(x_freq, dim=(-2, -1)) |
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B, C, H, W = x_freq.shape |
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mask = torch.ones((B, C, H, W), device=x.device) |
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crow, ccol = H // 2, W // 2 |
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mask[..., crow - threshold : crow + threshold, ccol - threshold : ccol + threshold] = scale |
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x_freq = x_freq * mask |
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x_freq = ifftshift(x_freq, dim=(-2, -1)) |
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x_filtered = ifftn(x_freq, dim=(-2, -1)).real |
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return x_filtered.to(dtype=x_in.dtype) |
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def apply_freeu( |
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resolution_idx: int, hidden_states: "torch.Tensor", res_hidden_states: "torch.Tensor", **freeu_kwargs |
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) -> Tuple["torch.Tensor", "torch.Tensor"]: |
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"""Applies the FreeU mechanism as introduced in https: |
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//arxiv.org/abs/2309.11497. Adapted from the official code repository: https://github.com/ChenyangSi/FreeU. |
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Args: |
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resolution_idx (`int`): Integer denoting the UNet block where FreeU is being applied. |
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hidden_states (`torch.Tensor`): Inputs to the underlying block. |
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res_hidden_states (`torch.Tensor`): Features from the skip block corresponding to the underlying block. |
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s1 (`float`): Scaling factor for stage 1 to attenuate the contributions of the skip features. |
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s2 (`float`): Scaling factor for stage 2 to attenuate the contributions of the skip features. |
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b1 (`float`): Scaling factor for stage 1 to amplify the contributions of backbone features. |
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b2 (`float`): Scaling factor for stage 2 to amplify the contributions of backbone features. |
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""" |
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if resolution_idx == 0: |
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num_half_channels = hidden_states.shape[1] // 2 |
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hidden_states[:, :num_half_channels] = hidden_states[:, :num_half_channels] * freeu_kwargs["b1"] |
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res_hidden_states = fourier_filter(res_hidden_states, threshold=1, scale=freeu_kwargs["s1"]) |
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if resolution_idx == 1: |
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num_half_channels = hidden_states.shape[1] // 2 |
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hidden_states[:, :num_half_channels] = hidden_states[:, :num_half_channels] * freeu_kwargs["b2"] |
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res_hidden_states = fourier_filter(res_hidden_states, threshold=1, scale=freeu_kwargs["s2"]) |
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return hidden_states, res_hidden_states |
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