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import os |
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import gc |
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import time |
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import numpy as np |
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import torch |
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import torchvision |
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from PIL import Image |
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from einops import rearrange, repeat |
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from omegaconf import OmegaConf |
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import safetensors.torch |
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from ldm.models.diffusion.ddim import DDIMSampler |
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from ldm.util import instantiate_from_config, ismap |
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from modules import shared, sd_hijack |
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cached_ldsr_model: torch.nn.Module = None |
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class LDSR: |
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def load_model_from_config(self, half_attention): |
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global cached_ldsr_model |
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if shared.opts.ldsr_cached and cached_ldsr_model is not None: |
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print("Loading model from cache") |
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model: torch.nn.Module = cached_ldsr_model |
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else: |
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print(f"Loading model from {self.modelPath}") |
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_, extension = os.path.splitext(self.modelPath) |
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if extension.lower() == ".safetensors": |
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pl_sd = safetensors.torch.load_file(self.modelPath, device="cpu") |
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else: |
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pl_sd = torch.load(self.modelPath, map_location="cpu") |
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sd = pl_sd["state_dict"] if "state_dict" in pl_sd else pl_sd |
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config = OmegaConf.load(self.yamlPath) |
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config.model.target = "ldm.models.diffusion.ddpm.LatentDiffusionV1" |
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model: torch.nn.Module = instantiate_from_config(config.model) |
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model.load_state_dict(sd, strict=False) |
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model = model.to(shared.device) |
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if half_attention: |
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model = model.half() |
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if shared.cmd_opts.opt_channelslast: |
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model = model.to(memory_format=torch.channels_last) |
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sd_hijack.model_hijack.hijack(model) |
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model.eval() |
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if shared.opts.ldsr_cached: |
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cached_ldsr_model = model |
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return {"model": model} |
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def __init__(self, model_path, yaml_path): |
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self.modelPath = model_path |
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self.yamlPath = yaml_path |
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@staticmethod |
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def run(model, selected_path, custom_steps, eta): |
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example = get_cond(selected_path) |
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n_runs = 1 |
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guider = None |
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ckwargs = None |
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ddim_use_x0_pred = False |
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temperature = 1. |
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eta = eta |
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custom_shape = None |
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height, width = example["image"].shape[1:3] |
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split_input = height >= 128 and width >= 128 |
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if split_input: |
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ks = 128 |
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stride = 64 |
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vqf = 4 |
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model.split_input_params = {"ks": (ks, ks), "stride": (stride, stride), |
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"vqf": vqf, |
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"patch_distributed_vq": True, |
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"tie_braker": False, |
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"clip_max_weight": 0.5, |
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"clip_min_weight": 0.01, |
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"clip_max_tie_weight": 0.5, |
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"clip_min_tie_weight": 0.01} |
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else: |
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if hasattr(model, "split_input_params"): |
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delattr(model, "split_input_params") |
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x_t = None |
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logs = None |
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for _ in range(n_runs): |
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if custom_shape is not None: |
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x_t = torch.randn(1, custom_shape[1], custom_shape[2], custom_shape[3]).to(model.device) |
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x_t = repeat(x_t, '1 c h w -> b c h w', b=custom_shape[0]) |
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logs = make_convolutional_sample(example, model, |
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custom_steps=custom_steps, |
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eta=eta, quantize_x0=False, |
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custom_shape=custom_shape, |
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temperature=temperature, noise_dropout=0., |
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corrector=guider, corrector_kwargs=ckwargs, x_T=x_t, |
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ddim_use_x0_pred=ddim_use_x0_pred |
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) |
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return logs |
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def super_resolution(self, image, steps=100, target_scale=2, half_attention=False): |
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model = self.load_model_from_config(half_attention) |
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diffusion_steps = int(steps) |
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eta = 1.0 |
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gc.collect() |
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if torch.cuda.is_available: |
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torch.cuda.empty_cache() |
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im_og = image |
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width_og, height_og = im_og.size |
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down_sample_rate = target_scale / 4 |
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wd = width_og * down_sample_rate |
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hd = height_og * down_sample_rate |
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width_downsampled_pre = int(np.ceil(wd)) |
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height_downsampled_pre = int(np.ceil(hd)) |
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if down_sample_rate != 1: |
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print( |
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f'Downsampling from [{width_og}, {height_og}] to [{width_downsampled_pre}, {height_downsampled_pre}]') |
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im_og = im_og.resize((width_downsampled_pre, height_downsampled_pre), Image.LANCZOS) |
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else: |
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print(f"Down sample rate is 1 from {target_scale} / 4 (Not downsampling)") |
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pad_w, pad_h = np.max(((2, 2), np.ceil(np.array(im_og.size) / 64).astype(int)), axis=0) * 64 - im_og.size |
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im_padded = Image.fromarray(np.pad(np.array(im_og), ((0, pad_h), (0, pad_w), (0, 0)), mode='edge')) |
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logs = self.run(model["model"], im_padded, diffusion_steps, eta) |
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sample = logs["sample"] |
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sample = sample.detach().cpu() |
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sample = torch.clamp(sample, -1., 1.) |
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sample = (sample + 1.) / 2. * 255 |
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sample = sample.numpy().astype(np.uint8) |
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sample = np.transpose(sample, (0, 2, 3, 1)) |
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a = Image.fromarray(sample[0]) |
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a = a.crop((0, 0) + tuple(np.array(im_og.size) * 4)) |
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del model |
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gc.collect() |
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if torch.cuda.is_available: |
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torch.cuda.empty_cache() |
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return a |
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def get_cond(selected_path): |
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example = {} |
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up_f = 4 |
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c = selected_path.convert('RGB') |
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c = torch.unsqueeze(torchvision.transforms.ToTensor()(c), 0) |
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c_up = torchvision.transforms.functional.resize(c, size=[up_f * c.shape[2], up_f * c.shape[3]], |
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antialias=True) |
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c_up = rearrange(c_up, '1 c h w -> 1 h w c') |
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c = rearrange(c, '1 c h w -> 1 h w c') |
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c = 2. * c - 1. |
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c = c.to(shared.device) |
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example["LR_image"] = c |
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example["image"] = c_up |
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return example |
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@torch.no_grad() |
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def convsample_ddim(model, cond, steps, shape, eta=1.0, callback=None, normals_sequence=None, |
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mask=None, x0=None, quantize_x0=False, temperature=1., score_corrector=None, |
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corrector_kwargs=None, x_t=None |
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): |
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ddim = DDIMSampler(model) |
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bs = shape[0] |
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shape = shape[1:] |
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print(f"Sampling with eta = {eta}; steps: {steps}") |
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samples, intermediates = ddim.sample(steps, batch_size=bs, shape=shape, conditioning=cond, callback=callback, |
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normals_sequence=normals_sequence, quantize_x0=quantize_x0, eta=eta, |
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mask=mask, x0=x0, temperature=temperature, verbose=False, |
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score_corrector=score_corrector, |
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corrector_kwargs=corrector_kwargs, x_t=x_t) |
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return samples, intermediates |
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@torch.no_grad() |
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def make_convolutional_sample(batch, model, custom_steps=None, eta=1.0, quantize_x0=False, custom_shape=None, temperature=1., noise_dropout=0., corrector=None, |
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corrector_kwargs=None, x_T=None, ddim_use_x0_pred=False): |
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log = {} |
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z, c, x, xrec, xc = model.get_input(batch, model.first_stage_key, |
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return_first_stage_outputs=True, |
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force_c_encode=not (hasattr(model, 'split_input_params') |
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and model.cond_stage_key == 'coordinates_bbox'), |
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return_original_cond=True) |
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if custom_shape is not None: |
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z = torch.randn(custom_shape) |
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print(f"Generating {custom_shape[0]} samples of shape {custom_shape[1:]}") |
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z0 = None |
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log["input"] = x |
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log["reconstruction"] = xrec |
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if ismap(xc): |
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log["original_conditioning"] = model.to_rgb(xc) |
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if hasattr(model, 'cond_stage_key'): |
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log[model.cond_stage_key] = model.to_rgb(xc) |
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else: |
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log["original_conditioning"] = xc if xc is not None else torch.zeros_like(x) |
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if model.cond_stage_model: |
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log[model.cond_stage_key] = xc if xc is not None else torch.zeros_like(x) |
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if model.cond_stage_key == 'class_label': |
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log[model.cond_stage_key] = xc[model.cond_stage_key] |
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with model.ema_scope("Plotting"): |
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t0 = time.time() |
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sample, intermediates = convsample_ddim(model, c, steps=custom_steps, shape=z.shape, |
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eta=eta, |
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quantize_x0=quantize_x0, mask=None, x0=z0, |
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temperature=temperature, score_corrector=corrector, corrector_kwargs=corrector_kwargs, |
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x_t=x_T) |
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t1 = time.time() |
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if ddim_use_x0_pred: |
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sample = intermediates['pred_x0'][-1] |
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x_sample = model.decode_first_stage(sample) |
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try: |
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x_sample_noquant = model.decode_first_stage(sample, force_not_quantize=True) |
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log["sample_noquant"] = x_sample_noquant |
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log["sample_diff"] = torch.abs(x_sample_noquant - x_sample) |
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except Exception: |
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pass |
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log["sample"] = x_sample |
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log["time"] = t1 - t0 |
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return log |
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