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import collections |
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import math |
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from itertools import repeat |
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from typing import Any |
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import numpy as np |
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import torch |
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from torch import conv2d, conv_transpose2d |
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def make_beta_schedule(device, schedule, n_timestep, linear_start=1e-4, linear_end=2e-2, cosine_s=8e-3): |
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if schedule == "linear": |
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betas = ( |
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torch.linspace(linear_start ** 0.5, linear_end ** 0.5, n_timestep, dtype=torch.float64) ** 2 |
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) |
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elif schedule == "cosine": |
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timesteps = (torch.arange(n_timestep + 1, dtype=torch.float64) / n_timestep + cosine_s).to(device) |
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alphas = timesteps / (1 + cosine_s) * np.pi / 2 |
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alphas = torch.cos(alphas).pow(2).to(device) |
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alphas = alphas / alphas[0] |
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betas = 1 - alphas[1:] / alphas[:-1] |
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betas = np.clip(betas, a_min=0, a_max=0.999) |
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elif schedule == "sqrt_linear": |
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betas = torch.linspace(linear_start, linear_end, n_timestep, dtype=torch.float64) |
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elif schedule == "sqrt": |
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betas = torch.linspace(linear_start, linear_end, n_timestep, dtype=torch.float64) ** 0.5 |
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else: |
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raise ValueError(f"schedule '{schedule}' unknown.") |
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return betas.numpy() |
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def make_ddim_sampling_parameters(alphacums, ddim_timesteps, eta, verbose=True): |
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alphas = alphacums[ddim_timesteps] |
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alphas_prev = np.asarray([alphacums[0]] + alphacums[ddim_timesteps[:-1]].tolist()) |
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sigmas = eta * np.sqrt((1 - alphas_prev) / (1 - alphas) * (1 - alphas / alphas_prev)) |
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if verbose: |
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print(f'Selected alphas for ddim sampler: a_t: {alphas}; a_(t-1): {alphas_prev}') |
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print(f'For the chosen value of eta, which is {eta}, ' |
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f'this results in the following sigma_t schedule for ddim sampler {sigmas}') |
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return sigmas, alphas, alphas_prev |
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def make_ddim_timesteps(ddim_discr_method, num_ddim_timesteps, num_ddpm_timesteps, verbose=True): |
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if ddim_discr_method == 'uniform': |
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c = num_ddpm_timesteps // num_ddim_timesteps |
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ddim_timesteps = np.asarray(list(range(0, num_ddpm_timesteps, c))) |
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elif ddim_discr_method == 'quad': |
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ddim_timesteps = ((np.linspace(0, np.sqrt(num_ddpm_timesteps * .8), num_ddim_timesteps)) ** 2).astype(int) |
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else: |
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raise NotImplementedError(f'There is no ddim discretization method called "{ddim_discr_method}"') |
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steps_out = ddim_timesteps + 1 |
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if verbose: |
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print(f'Selected timesteps for ddim sampler: {steps_out}') |
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return steps_out |
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def noise_like(shape, device, repeat=False): |
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repeat_noise = lambda: torch.randn((1, *shape[1:]), device=device).repeat(shape[0], *((1,) * (len(shape) - 1))) |
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noise = lambda: torch.randn(shape, device=device) |
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return repeat_noise() if repeat else noise() |
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def timestep_embedding(device, timesteps, dim, max_period=10000, repeat_only=False): |
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""" |
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Create sinusoidal timestep embeddings. |
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:param timesteps: a 1-D Tensor of N indices, one per batch element. |
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These may be fractional. |
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:param dim: the dimension of the output. |
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:param max_period: controls the minimum frequency of the embeddings. |
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:return: an [N x dim] Tensor of positional embeddings. |
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""" |
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half = dim // 2 |
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freqs = torch.exp( |
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-math.log(max_period) * torch.arange(start=0, end=half, dtype=torch.float32) / half |
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).to(device=device) |
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args = timesteps[:, None].float() * freqs[None] |
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embedding = torch.cat([torch.cos(args), torch.sin(args)], dim=-1) |
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if dim % 2: |
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embedding = torch.cat([embedding, torch.zeros_like(embedding[:, :1])], dim=-1) |
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return embedding |
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def normalize_2nd_moment(x, dim=1, eps=1e-8): |
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return x * (x.square().mean(dim=dim, keepdim=True) + eps).rsqrt() |
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class EasyDict(dict): |
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"""Convenience class that behaves like a dict but allows access with the attribute syntax.""" |
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def __getattr__(self, name: str) -> Any: |
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try: |
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return self[name] |
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except KeyError: |
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raise AttributeError(name) |
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def __setattr__(self, name: str, value: Any) -> None: |
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self[name] = value |
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def __delattr__(self, name: str) -> None: |
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del self[name] |
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def _bias_act_ref(x, b=None, dim=1, act='linear', alpha=None, gain=None, clamp=None): |
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"""Slow reference implementation of `bias_act()` using standard TensorFlow ops. |
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""" |
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assert isinstance(x, torch.Tensor) |
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assert clamp is None or clamp >= 0 |
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spec = activation_funcs[act] |
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alpha = float(alpha if alpha is not None else spec.def_alpha) |
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gain = float(gain if gain is not None else spec.def_gain) |
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clamp = float(clamp if clamp is not None else -1) |
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if b is not None: |
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assert isinstance(b, torch.Tensor) and b.ndim == 1 |
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assert 0 <= dim < x.ndim |
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assert b.shape[0] == x.shape[dim] |
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x = x + b.reshape([-1 if i == dim else 1 for i in range(x.ndim)]) |
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alpha = float(alpha) |
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x = spec.func(x, alpha=alpha) |
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gain = float(gain) |
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if gain != 1: |
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x = x * gain |
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if clamp >= 0: |
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x = x.clamp(-clamp, clamp) |
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return x |
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def bias_act(x, b=None, dim=1, act='linear', alpha=None, gain=None, clamp=None, impl='ref'): |
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r"""Fused bias and activation function. |
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Adds bias `b` to activation tensor `x`, evaluates activation function `act`, |
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and scales the result by `gain`. Each of the steps is optional. In most cases, |
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the fused op is considerably more efficient than performing the same calculation |
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using standard PyTorch ops. It supports first and second order gradients, |
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but not third order gradients. |
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Args: |
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x: Input activation tensor. Can be of any shape. |
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b: Bias vector, or `None` to disable. Must be a 1D tensor of the same type |
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as `x`. The shape must be known, and it must match the dimension of `x` |
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corresponding to `dim`. |
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dim: The dimension in `x` corresponding to the elements of `b`. |
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The value of `dim` is ignored if `b` is not specified. |
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act: Name of the activation function to evaluate, or `"linear"` to disable. |
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Can be e.g. `"relu"`, `"lrelu"`, `"tanh"`, `"sigmoid"`, `"swish"`, etc. |
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See `activation_funcs` for a full list. `None` is not allowed. |
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alpha: Shape parameter for the activation function, or `None` to use the default. |
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gain: Scaling factor for the output tensor, or `None` to use default. |
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See `activation_funcs` for the default scaling of each activation function. |
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If unsure, consider specifying 1. |
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clamp: Clamp the output values to `[-clamp, +clamp]`, or `None` to disable |
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the clamping (default). |
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impl: Name of the implementation to use. Can be `"ref"` or `"cuda"` (default). |
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Returns: |
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Tensor of the same shape and datatype as `x`. |
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""" |
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assert isinstance(x, torch.Tensor) |
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assert impl in ['ref', 'cuda'] |
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return _bias_act_ref(x=x, b=b, dim=dim, act=act, alpha=alpha, gain=gain, clamp=clamp) |
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def _get_filter_size(f): |
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if f is None: |
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return 1, 1 |
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assert isinstance(f, torch.Tensor) and f.ndim in [1, 2] |
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fw = f.shape[-1] |
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fh = f.shape[0] |
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fw = int(fw) |
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fh = int(fh) |
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assert fw >= 1 and fh >= 1 |
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return fw, fh |
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def _get_weight_shape(w): |
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shape = [int(sz) for sz in w.shape] |
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return shape |
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def _parse_scaling(scaling): |
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if isinstance(scaling, int): |
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scaling = [scaling, scaling] |
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assert isinstance(scaling, (list, tuple)) |
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assert all(isinstance(x, int) for x in scaling) |
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sx, sy = scaling |
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assert sx >= 1 and sy >= 1 |
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return sx, sy |
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def _parse_padding(padding): |
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if isinstance(padding, int): |
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padding = [padding, padding] |
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assert isinstance(padding, (list, tuple)) |
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assert all(isinstance(x, int) for x in padding) |
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if len(padding) == 2: |
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padx, pady = padding |
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padding = [padx, padx, pady, pady] |
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padx0, padx1, pady0, pady1 = padding |
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return padx0, padx1, pady0, pady1 |
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def setup_filter(f, device=torch.device('cpu'), normalize=True, flip_filter=False, gain=1, separable=None): |
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r"""Convenience function to setup 2D FIR filter for `upfirdn2d()`. |
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Args: |
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f: Torch tensor, numpy array, or python list of the shape |
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`[filter_height, filter_width]` (non-separable), |
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`[filter_taps]` (separable), |
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`[]` (impulse), or |
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`None` (identity). |
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device: Result device (default: cpu). |
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normalize: Normalize the filter so that it retains the magnitude |
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for constant input signal (DC)? (default: True). |
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flip_filter: Flip the filter? (default: False). |
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gain: Overall scaling factor for signal magnitude (default: 1). |
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separable: Return a separable filter? (default: select automatically). |
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Returns: |
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Float32 tensor of the shape |
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`[filter_height, filter_width]` (non-separable) or |
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`[filter_taps]` (separable). |
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""" |
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if f is None: |
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f = 1 |
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f = torch.as_tensor(f, dtype=torch.float32) |
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assert f.ndim in [0, 1, 2] |
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assert f.numel() > 0 |
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if f.ndim == 0: |
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f = f[np.newaxis] |
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if separable is None: |
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separable = (f.ndim == 1 and f.numel() >= 8) |
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if f.ndim == 1 and not separable: |
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f = f.ger(f) |
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assert f.ndim == (1 if separable else 2) |
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if normalize: |
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f /= f.sum() |
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if flip_filter: |
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f = f.flip(list(range(f.ndim))) |
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f = f * (gain ** (f.ndim / 2)) |
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f = f.to(device=device) |
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return f |
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def _ntuple(n): |
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def parse(x): |
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if isinstance(x, collections.abc.Iterable): |
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return x |
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return tuple(repeat(x, n)) |
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return parse |
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to_2tuple = _ntuple(2) |
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activation_funcs = { |
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'linear': EasyDict(func=lambda x, **_: x, def_alpha=0, def_gain=1, cuda_idx=1, ref='', has_2nd_grad=False), |
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'relu': EasyDict(func=lambda x, **_: torch.nn.functional.relu(x), def_alpha=0, def_gain=np.sqrt(2), cuda_idx=2, |
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ref='y', has_2nd_grad=False), |
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'lrelu': EasyDict(func=lambda x, alpha, **_: torch.nn.functional.leaky_relu(x, alpha), def_alpha=0.2, |
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def_gain=np.sqrt(2), cuda_idx=3, ref='y', has_2nd_grad=False), |
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'tanh': EasyDict(func=lambda x, **_: torch.tanh(x), def_alpha=0, def_gain=1, cuda_idx=4, ref='y', |
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has_2nd_grad=True), |
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'sigmoid': EasyDict(func=lambda x, **_: torch.sigmoid(x), def_alpha=0, def_gain=1, cuda_idx=5, ref='y', |
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has_2nd_grad=True), |
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'elu': EasyDict(func=lambda x, **_: torch.nn.functional.elu(x), def_alpha=0, def_gain=1, cuda_idx=6, ref='y', |
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has_2nd_grad=True), |
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'selu': EasyDict(func=lambda x, **_: torch.nn.functional.selu(x), def_alpha=0, def_gain=1, cuda_idx=7, ref='y', |
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has_2nd_grad=True), |
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'softplus': EasyDict(func=lambda x, **_: torch.nn.functional.softplus(x), def_alpha=0, def_gain=1, cuda_idx=8, |
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ref='y', has_2nd_grad=True), |
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'swish': EasyDict(func=lambda x, **_: torch.sigmoid(x) * x, def_alpha=0, def_gain=np.sqrt(2), cuda_idx=9, ref='x', |
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has_2nd_grad=True), |
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} |
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def upfirdn2d(x, f, up=1, down=1, padding=0, flip_filter=False, gain=1, impl='cuda'): |
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r"""Pad, upsample, filter, and downsample a batch of 2D images. |
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Performs the following sequence of operations for each channel: |
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1. Upsample the image by inserting N-1 zeros after each pixel (`up`). |
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2. Pad the image with the specified number of zeros on each side (`padding`). |
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Negative padding corresponds to cropping the image. |
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3. Convolve the image with the specified 2D FIR filter (`f`), shrinking it |
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so that the footprint of all output pixels lies within the input image. |
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4. Downsample the image by keeping every Nth pixel (`down`). |
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This sequence of operations bears close resemblance to scipy.signal.upfirdn(). |
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The fused op is considerably more efficient than performing the same calculation |
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using standard PyTorch ops. It supports gradients of arbitrary order. |
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Args: |
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x: Float32/float64/float16 input tensor of the shape |
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`[batch_size, num_channels, in_height, in_width]`. |
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f: Float32 FIR filter of the shape |
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`[filter_height, filter_width]` (non-separable), |
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`[filter_taps]` (separable), or |
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`None` (identity). |
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up: Integer upsampling factor. Can be a single int or a list/tuple |
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`[x, y]` (default: 1). |
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down: Integer downsampling factor. Can be a single int or a list/tuple |
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`[x, y]` (default: 1). |
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padding: Padding with respect to the upsampled image. Can be a single number |
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or a list/tuple `[x, y]` or `[x_before, x_after, y_before, y_after]` |
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(default: 0). |
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flip_filter: False = convolution, True = correlation (default: False). |
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gain: Overall scaling factor for signal magnitude (default: 1). |
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impl: Implementation to use. Can be `'ref'` or `'cuda'` (default: `'cuda'`). |
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Returns: |
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Tensor of the shape `[batch_size, num_channels, out_height, out_width]`. |
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""" |
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return _upfirdn2d_ref(x, f, up=up, down=down, padding=padding, flip_filter=flip_filter, gain=gain) |
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def _upfirdn2d_ref(x, f, up=1, down=1, padding=0, flip_filter=False, gain=1): |
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"""Slow reference implementation of `upfirdn2d()` using standard PyTorch ops. |
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""" |
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assert isinstance(x, torch.Tensor) and x.ndim == 4 |
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if f is None: |
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f = torch.ones([1, 1], dtype=torch.float32, device=x.device) |
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assert isinstance(f, torch.Tensor) and f.ndim in [1, 2] |
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assert f.dtype == torch.float32 and not f.requires_grad |
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batch_size, num_channels, in_height, in_width = x.shape |
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upx, upy = up, up |
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downx, downy = down, down |
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padx0, padx1, pady0, pady1 = padding[0], padding[1], padding[2], padding[3] |
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x = x.reshape([batch_size, num_channels, in_height, 1, in_width, 1]) |
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x = torch.nn.functional.pad(x, [0, upx - 1, 0, 0, 0, upy - 1]) |
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x = x.reshape([batch_size, num_channels, in_height * upy, in_width * upx]) |
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x = torch.nn.functional.pad(x, [max(padx0, 0), max(padx1, 0), max(pady0, 0), max(pady1, 0)]) |
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x = x[:, :, max(-pady0, 0): x.shape[2] - max(-pady1, 0), max(-padx0, 0): x.shape[3] - max(-padx1, 0)] |
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f = f * (gain ** (f.ndim / 2)) |
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f = f.to(x.dtype) |
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if not flip_filter: |
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f = f.flip(list(range(f.ndim))) |
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f = f[np.newaxis, np.newaxis].repeat([num_channels, 1] + [1] * f.ndim) |
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if f.ndim == 4: |
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x = conv2d(input=x, weight=f, groups=num_channels) |
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else: |
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x = conv2d(input=x, weight=f.unsqueeze(2), groups=num_channels) |
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x = conv2d(input=x, weight=f.unsqueeze(3), groups=num_channels) |
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x = x[:, :, ::downy, ::downx] |
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return x |
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def downsample2d(x, f, down=2, padding=0, flip_filter=False, gain=1, impl='cuda'): |
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r"""Downsample a batch of 2D images using the given 2D FIR filter. |
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By default, the result is padded so that its shape is a fraction of the input. |
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User-specified padding is applied on top of that, with negative values |
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indicating cropping. Pixels outside the image are assumed to be zero. |
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Args: |
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x: Float32/float64/float16 input tensor of the shape |
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`[batch_size, num_channels, in_height, in_width]`. |
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f: Float32 FIR filter of the shape |
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`[filter_height, filter_width]` (non-separable), |
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`[filter_taps]` (separable), or |
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`None` (identity). |
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down: Integer downsampling factor. Can be a single int or a list/tuple |
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`[x, y]` (default: 1). |
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padding: Padding with respect to the input. Can be a single number or a |
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list/tuple `[x, y]` or `[x_before, x_after, y_before, y_after]` |
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(default: 0). |
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flip_filter: False = convolution, True = correlation (default: False). |
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gain: Overall scaling factor for signal magnitude (default: 1). |
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impl: Implementation to use. Can be `'ref'` or `'cuda'` (default: `'cuda'`). |
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Returns: |
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Tensor of the shape `[batch_size, num_channels, out_height, out_width]`. |
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""" |
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downx, downy = _parse_scaling(down) |
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padx0, padx1, pady0, pady1 = padding, padding, padding, padding |
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fw, fh = _get_filter_size(f) |
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p = [ |
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padx0 + (fw - downx + 1) // 2, |
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padx1 + (fw - downx) // 2, |
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pady0 + (fh - downy + 1) // 2, |
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pady1 + (fh - downy) // 2, |
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] |
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return upfirdn2d(x, f, down=down, padding=p, flip_filter=flip_filter, gain=gain, impl=impl) |
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def upsample2d(x, f, up=2, padding=0, flip_filter=False, gain=1, impl='cuda'): |
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r"""Upsample a batch of 2D images using the given 2D FIR filter. |
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|
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By default, the result is padded so that its shape is a multiple of the input. |
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User-specified padding is applied on top of that, with negative values |
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indicating cropping. Pixels outside the image are assumed to be zero. |
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|
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Args: |
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x: Float32/float64/float16 input tensor of the shape |
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`[batch_size, num_channels, in_height, in_width]`. |
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f: Float32 FIR filter of the shape |
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`[filter_height, filter_width]` (non-separable), |
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`[filter_taps]` (separable), or |
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`None` (identity). |
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up: Integer upsampling factor. Can be a single int or a list/tuple |
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`[x, y]` (default: 1). |
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padding: Padding with respect to the output. Can be a single number or a |
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list/tuple `[x, y]` or `[x_before, x_after, y_before, y_after]` |
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(default: 0). |
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flip_filter: False = convolution, True = correlation (default: False). |
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gain: Overall scaling factor for signal magnitude (default: 1). |
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impl: Implementation to use. Can be `'ref'` or `'cuda'` (default: `'cuda'`). |
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Returns: |
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Tensor of the shape `[batch_size, num_channels, out_height, out_width]`. |
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""" |
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upx, upy = _parse_scaling(up) |
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|
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padx0, padx1, pady0, pady1 = _parse_padding(padding) |
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|
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fw, fh = _get_filter_size(f) |
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p = [ |
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padx0 + (fw + upx - 1) // 2, |
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padx1 + (fw - upx) // 2, |
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pady0 + (fh + upy - 1) // 2, |
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pady1 + (fh - upy) // 2, |
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] |
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return upfirdn2d(x, f, up=up, padding=p, flip_filter=flip_filter, gain=gain * upx * upy, impl=impl) |
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class MinibatchStdLayer(torch.nn.Module): |
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def __init__(self, group_size, num_channels=1): |
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super().__init__() |
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self.group_size = group_size |
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self.num_channels = num_channels |
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def forward(self, x): |
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N, C, H, W = x.shape |
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G = torch.min(torch.as_tensor(self.group_size), |
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torch.as_tensor(N)) if self.group_size is not None else N |
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F = self.num_channels |
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c = C // F |
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y = x.reshape(G, -1, F, c, H, |
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W) |
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y = y - y.mean(dim=0) |
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y = y.square().mean(dim=0) |
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y = (y + 1e-8).sqrt() |
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y = y.mean(dim=[2, 3, 4]) |
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y = y.reshape(-1, F, 1, 1) |
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y = y.repeat(G, 1, H, W) |
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x = torch.cat([x, y], dim=1) |
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return x |
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class FullyConnectedLayer(torch.nn.Module): |
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def __init__(self, |
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in_features, |
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out_features, |
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bias=True, |
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activation='linear', |
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lr_multiplier=1, |
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bias_init=0, |
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): |
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super().__init__() |
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self.weight = torch.nn.Parameter(torch.randn([out_features, in_features]) / lr_multiplier) |
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self.bias = torch.nn.Parameter(torch.full([out_features], np.float32(bias_init))) if bias else None |
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self.activation = activation |
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self.weight_gain = lr_multiplier / np.sqrt(in_features) |
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self.bias_gain = lr_multiplier |
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def forward(self, x): |
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w = self.weight * self.weight_gain |
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b = self.bias |
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if b is not None and self.bias_gain != 1: |
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b = b * self.bias_gain |
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|
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if self.activation == 'linear' and b is not None: |
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x = x.matmul(w.t()) |
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out = x + b.reshape([-1 if i == x.ndim - 1 else 1 for i in range(x.ndim)]) |
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else: |
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x = x.matmul(w.t()) |
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out = bias_act(x, b, act=self.activation, dim=x.ndim - 1) |
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return out |
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def _conv2d_wrapper(x, w, stride=1, padding=0, groups=1, transpose=False, flip_weight=True): |
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"""Wrapper for the underlying `conv2d()` and `conv_transpose2d()` implementations. |
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""" |
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out_channels, in_channels_per_group, kh, kw = _get_weight_shape(w) |
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if not flip_weight: |
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w = w.flip([2, 3]) |
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if kw == 1 and kh == 1 and stride == 1 and padding in [0, [0, 0], (0, 0)] and not transpose: |
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if x.stride()[1] == 1 and min(out_channels, in_channels_per_group) < 64: |
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if out_channels <= 4 and groups == 1: |
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in_shape = x.shape |
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x = w.squeeze(3).squeeze(2) @ x.reshape([in_shape[0], in_channels_per_group, -1]) |
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x = x.reshape([in_shape[0], out_channels, in_shape[2], in_shape[3]]) |
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else: |
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x = x.to(memory_format=torch.contiguous_format) |
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w = w.to(memory_format=torch.contiguous_format) |
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x = conv2d(x, w, groups=groups) |
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return x.to(memory_format=torch.channels_last) |
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op = conv_transpose2d if transpose else conv2d |
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return op(x, w, stride=stride, padding=padding, groups=groups) |
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def conv2d_resample(x, w, f=None, up=1, down=1, padding=0, groups=1, flip_weight=True, flip_filter=False): |
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r"""2D convolution with optional up/downsampling. |
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Padding is performed only once at the beginning, not between the operations. |
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Args: |
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x: Input tensor of shape |
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`[batch_size, in_channels, in_height, in_width]`. |
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w: Weight tensor of shape |
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`[out_channels, in_channels//groups, kernel_height, kernel_width]`. |
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f: Low-pass filter for up/downsampling. Must be prepared beforehand by |
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calling setup_filter(). None = identity (default). |
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up: Integer upsampling factor (default: 1). |
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down: Integer downsampling factor (default: 1). |
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padding: Padding with respect to the upsampled image. Can be a single number |
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or a list/tuple `[x, y]` or `[x_before, x_after, y_before, y_after]` |
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(default: 0). |
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groups: Split input channels into N groups (default: 1). |
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flip_weight: False = convolution, True = correlation (default: True). |
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flip_filter: False = convolution, True = correlation (default: False). |
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Returns: |
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Tensor of the shape `[batch_size, num_channels, out_height, out_width]`. |
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""" |
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|
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assert isinstance(x, torch.Tensor) and (x.ndim == 4) |
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assert isinstance(w, torch.Tensor) and (w.ndim == 4) and (w.dtype == x.dtype) |
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assert f is None or (isinstance(f, torch.Tensor) and f.ndim in [1, 2] and f.dtype == torch.float32) |
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assert isinstance(up, int) and (up >= 1) |
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assert isinstance(down, int) and (down >= 1) |
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out_channels, in_channels_per_group, kh, kw = _get_weight_shape(w) |
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fw, fh = _get_filter_size(f) |
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px0, px1, py0, py1 = padding, padding, padding, padding |
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if up > 1: |
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px0 += (fw + up - 1) // 2 |
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px1 += (fw - up) // 2 |
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py0 += (fh + up - 1) // 2 |
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py1 += (fh - up) // 2 |
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if down > 1: |
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px0 += (fw - down + 1) // 2 |
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px1 += (fw - down) // 2 |
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py0 += (fh - down + 1) // 2 |
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py1 += (fh - down) // 2 |
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if kw == 1 and kh == 1 and (down > 1 and up == 1): |
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x = upfirdn2d(x=x, f=f, down=down, padding=[px0, px1, py0, py1], flip_filter=flip_filter) |
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x = _conv2d_wrapper(x=x, w=w, groups=groups, flip_weight=flip_weight) |
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return x |
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if kw == 1 and kh == 1 and (up > 1 and down == 1): |
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x = _conv2d_wrapper(x=x, w=w, groups=groups, flip_weight=flip_weight) |
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x = upfirdn2d(x=x, f=f, up=up, padding=[px0, px1, py0, py1], gain=up ** 2, flip_filter=flip_filter) |
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return x |
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if down > 1 and up == 1: |
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x = upfirdn2d(x=x, f=f, padding=[px0, px1, py0, py1], flip_filter=flip_filter) |
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x = _conv2d_wrapper(x=x, w=w, stride=down, groups=groups, flip_weight=flip_weight) |
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return x |
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if up > 1: |
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if groups == 1: |
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w = w.transpose(0, 1) |
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else: |
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w = w.reshape(groups, out_channels // groups, in_channels_per_group, kh, kw) |
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w = w.transpose(1, 2) |
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w = w.reshape(groups * in_channels_per_group, out_channels // groups, kh, kw) |
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px0 -= kw - 1 |
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px1 -= kw - up |
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py0 -= kh - 1 |
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py1 -= kh - up |
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pxt = max(min(-px0, -px1), 0) |
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pyt = max(min(-py0, -py1), 0) |
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x = _conv2d_wrapper(x=x, w=w, stride=up, padding=[pyt, pxt], groups=groups, transpose=True, |
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flip_weight=(not flip_weight)) |
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x = upfirdn2d(x=x, f=f, padding=[px0 + pxt, px1 + pxt, py0 + pyt, py1 + pyt], gain=up ** 2, |
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flip_filter=flip_filter) |
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if down > 1: |
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x = upfirdn2d(x=x, f=f, down=down, flip_filter=flip_filter) |
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return x |
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if up == 1 and down == 1: |
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if px0 == px1 and py0 == py1 and px0 >= 0 and py0 >= 0: |
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return _conv2d_wrapper(x=x, w=w, padding=[py0, px0], groups=groups, flip_weight=flip_weight) |
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x = upfirdn2d(x=x, f=(f if up > 1 else None), up=up, padding=[px0, px1, py0, py1], gain=up ** 2, |
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flip_filter=flip_filter) |
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x = _conv2d_wrapper(x=x, w=w, groups=groups, flip_weight=flip_weight) |
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if down > 1: |
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x = upfirdn2d(x=x, f=f, down=down, flip_filter=flip_filter) |
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return x |
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|
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class Conv2dLayer(torch.nn.Module): |
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def __init__(self, |
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in_channels, |
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out_channels, |
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kernel_size, |
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bias=True, |
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activation='linear', |
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up=1, |
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down=1, |
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resample_filter=[1, 3, 3, 1], |
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conv_clamp=None, |
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channels_last=False, |
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trainable=True, |
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): |
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super().__init__() |
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self.activation = activation |
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self.up = up |
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self.down = down |
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self.register_buffer('resample_filter', setup_filter(resample_filter)) |
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self.conv_clamp = conv_clamp |
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self.padding = kernel_size // 2 |
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self.weight_gain = 1 / np.sqrt(in_channels * (kernel_size ** 2)) |
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self.act_gain = activation_funcs[activation].def_gain |
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|
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memory_format = torch.channels_last if channels_last else torch.contiguous_format |
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weight = torch.randn([out_channels, in_channels, kernel_size, kernel_size]).to(memory_format=memory_format) |
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bias = torch.zeros([out_channels]) if bias else None |
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if trainable: |
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self.weight = torch.nn.Parameter(weight) |
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self.bias = torch.nn.Parameter(bias) if bias is not None else None |
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else: |
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self.register_buffer('weight', weight) |
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if bias is not None: |
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self.register_buffer('bias', bias) |
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else: |
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self.bias = None |
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|
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def forward(self, x, gain=1): |
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w = self.weight * self.weight_gain |
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x = conv2d_resample(x=x, w=w, f=self.resample_filter, up=self.up, down=self.down, |
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padding=self.padding) |
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|
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act_gain = self.act_gain * gain |
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act_clamp = self.conv_clamp * gain if self.conv_clamp is not None else None |
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out = bias_act(x, self.bias, act=self.activation, gain=act_gain, clamp=act_clamp) |
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return out |
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|
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def torch_gc(): |
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if torch.cuda.is_available(): |
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torch.cuda.empty_cache() |
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torch.cuda.ipc_collect() |
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