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import os | |
import numpy as np | |
import PIL | |
import torch | |
from PIL import Image | |
from torch.utils.data import Dataset, DataLoader, Sampler | |
from torchvision import transforms | |
from collections import defaultdict | |
from random import shuffle, choices | |
import random | |
import tqdm | |
from modules import devices, shared | |
import re | |
from ldm.modules.distributions.distributions import DiagonalGaussianDistribution | |
re_numbers_at_start = re.compile(r"^[-\d]+\s*") | |
class DatasetEntry: | |
def __init__(self, filename=None, filename_text=None, latent_dist=None, latent_sample=None, cond=None, cond_text=None, pixel_values=None, weight=None): | |
self.filename = filename | |
self.filename_text = filename_text | |
self.weight = weight | |
self.latent_dist = latent_dist | |
self.latent_sample = latent_sample | |
self.cond = cond | |
self.cond_text = cond_text | |
self.pixel_values = pixel_values | |
class PersonalizedBase(Dataset): | |
def __init__(self, data_root, width, height, repeats, flip_p=0.5, placeholder_token="*", model=None, cond_model=None, device=None, template_file=None, include_cond=False, batch_size=1, gradient_step=1, shuffle_tags=False, tag_drop_out=0, latent_sampling_method='once', varsize=False, use_weight=False): | |
re_word = re.compile(shared.opts.dataset_filename_word_regex) if shared.opts.dataset_filename_word_regex else None | |
self.placeholder_token = placeholder_token | |
self.flip = transforms.RandomHorizontalFlip(p=flip_p) | |
self.dataset = [] | |
with open(template_file, "r") as file: | |
lines = [x.strip() for x in file.readlines()] | |
self.lines = lines | |
assert data_root, 'dataset directory not specified' | |
assert os.path.isdir(data_root), "Dataset directory doesn't exist" | |
assert os.listdir(data_root), "Dataset directory is empty" | |
self.image_paths = [os.path.join(data_root, file_path) for file_path in os.listdir(data_root)] | |
self.shuffle_tags = shuffle_tags | |
self.tag_drop_out = tag_drop_out | |
groups = defaultdict(list) | |
print("Preparing dataset...") | |
for path in tqdm.tqdm(self.image_paths): | |
alpha_channel = None | |
if shared.state.interrupted: | |
raise Exception("interrupted") | |
try: | |
image = Image.open(path) | |
#Currently does not work for single color transparency | |
#We would need to read image.info['transparency'] for that | |
if use_weight and 'A' in image.getbands(): | |
alpha_channel = image.getchannel('A') | |
image = image.convert('RGB') | |
if not varsize: | |
image = image.resize((width, height), PIL.Image.BICUBIC) | |
except Exception: | |
continue | |
text_filename = f"{os.path.splitext(path)[0]}.txt" | |
filename = os.path.basename(path) | |
if os.path.exists(text_filename): | |
with open(text_filename, "r", encoding="utf8") as file: | |
filename_text = file.read() | |
else: | |
filename_text = os.path.splitext(filename)[0] | |
filename_text = re.sub(re_numbers_at_start, '', filename_text) | |
if re_word: | |
tokens = re_word.findall(filename_text) | |
filename_text = (shared.opts.dataset_filename_join_string or "").join(tokens) | |
npimage = np.array(image).astype(np.uint8) | |
npimage = (npimage / 127.5 - 1.0).astype(np.float32) | |
torchdata = torch.from_numpy(npimage).permute(2, 0, 1).to(device=device, dtype=torch.float32) | |
latent_sample = None | |
with devices.autocast(): | |
latent_dist = model.encode_first_stage(torchdata.unsqueeze(dim=0)) | |
#Perform latent sampling, even for random sampling. | |
#We need the sample dimensions for the weights | |
if latent_sampling_method == "deterministic": | |
if isinstance(latent_dist, DiagonalGaussianDistribution): | |
# Works only for DiagonalGaussianDistribution | |
latent_dist.std = 0 | |
else: | |
latent_sampling_method = "once" | |
latent_sample = model.get_first_stage_encoding(latent_dist).squeeze().to(devices.cpu) | |
if use_weight and alpha_channel is not None: | |
channels, *latent_size = latent_sample.shape | |
weight_img = alpha_channel.resize(latent_size) | |
npweight = np.array(weight_img).astype(np.float32) | |
#Repeat for every channel in the latent sample | |
weight = torch.tensor([npweight] * channels).reshape([channels] + latent_size) | |
#Normalize the weight to a minimum of 0 and a mean of 1, that way the loss will be comparable to default. | |
weight -= weight.min() | |
weight /= weight.mean() | |
elif use_weight: | |
#If an image does not have a alpha channel, add a ones weight map anyway so we can stack it later | |
weight = torch.ones(latent_sample.shape) | |
else: | |
weight = None | |
if latent_sampling_method == "random": | |
entry = DatasetEntry(filename=path, filename_text=filename_text, latent_dist=latent_dist, weight=weight) | |
else: | |
entry = DatasetEntry(filename=path, filename_text=filename_text, latent_sample=latent_sample, weight=weight) | |
if not (self.tag_drop_out != 0 or self.shuffle_tags): | |
entry.cond_text = self.create_text(filename_text) | |
if include_cond and not (self.tag_drop_out != 0 or self.shuffle_tags): | |
with devices.autocast(): | |
entry.cond = cond_model([entry.cond_text]).to(devices.cpu).squeeze(0) | |
groups[image.size].append(len(self.dataset)) | |
self.dataset.append(entry) | |
del torchdata | |
del latent_dist | |
del latent_sample | |
del weight | |
self.length = len(self.dataset) | |
self.groups = list(groups.values()) | |
assert self.length > 0, "No images have been found in the dataset." | |
self.batch_size = min(batch_size, self.length) | |
self.gradient_step = min(gradient_step, self.length // self.batch_size) | |
self.latent_sampling_method = latent_sampling_method | |
if len(groups) > 1: | |
print("Buckets:") | |
for (w, h), ids in sorted(groups.items(), key=lambda x: x[0]): | |
print(f" {w}x{h}: {len(ids)}") | |
print() | |
def create_text(self, filename_text): | |
text = random.choice(self.lines) | |
tags = filename_text.split(',') | |
if self.tag_drop_out != 0: | |
tags = [t for t in tags if random.random() > self.tag_drop_out] | |
if self.shuffle_tags: | |
random.shuffle(tags) | |
text = text.replace("[filewords]", ','.join(tags)) | |
text = text.replace("[name]", self.placeholder_token) | |
return text | |
def __len__(self): | |
return self.length | |
def __getitem__(self, i): | |
entry = self.dataset[i] | |
if self.tag_drop_out != 0 or self.shuffle_tags: | |
entry.cond_text = self.create_text(entry.filename_text) | |
if self.latent_sampling_method == "random": | |
entry.latent_sample = shared.sd_model.get_first_stage_encoding(entry.latent_dist).to(devices.cpu) | |
return entry | |
class GroupedBatchSampler(Sampler): | |
def __init__(self, data_source: PersonalizedBase, batch_size: int): | |
super().__init__(data_source) | |
n = len(data_source) | |
self.groups = data_source.groups | |
self.len = n_batch = n // batch_size | |
expected = [len(g) / n * n_batch * batch_size for g in data_source.groups] | |
self.base = [int(e) // batch_size for e in expected] | |
self.n_rand_batches = nrb = n_batch - sum(self.base) | |
self.probs = [e%batch_size/nrb/batch_size if nrb>0 else 0 for e in expected] | |
self.batch_size = batch_size | |
def __len__(self): | |
return self.len | |
def __iter__(self): | |
b = self.batch_size | |
for g in self.groups: | |
shuffle(g) | |
batches = [] | |
for g in self.groups: | |
batches.extend(g[i*b:(i+1)*b] for i in range(len(g) // b)) | |
for _ in range(self.n_rand_batches): | |
rand_group = choices(self.groups, self.probs)[0] | |
batches.append(choices(rand_group, k=b)) | |
shuffle(batches) | |
yield from batches | |
class PersonalizedDataLoader(DataLoader): | |
def __init__(self, dataset, latent_sampling_method="once", batch_size=1, pin_memory=False): | |
super(PersonalizedDataLoader, self).__init__(dataset, batch_sampler=GroupedBatchSampler(dataset, batch_size), pin_memory=pin_memory) | |
if latent_sampling_method == "random": | |
self.collate_fn = collate_wrapper_random | |
else: | |
self.collate_fn = collate_wrapper | |
class BatchLoader: | |
def __init__(self, data): | |
self.cond_text = [entry.cond_text for entry in data] | |
self.cond = [entry.cond for entry in data] | |
self.latent_sample = torch.stack([entry.latent_sample for entry in data]).squeeze(1) | |
if all(entry.weight is not None for entry in data): | |
self.weight = torch.stack([entry.weight for entry in data]).squeeze(1) | |
else: | |
self.weight = None | |
#self.emb_index = [entry.emb_index for entry in data] | |
#print(self.latent_sample.device) | |
def pin_memory(self): | |
self.latent_sample = self.latent_sample.pin_memory() | |
return self | |
def collate_wrapper(batch): | |
return BatchLoader(batch) | |
class BatchLoaderRandom(BatchLoader): | |
def __init__(self, data): | |
super().__init__(data) | |
def pin_memory(self): | |
return self | |
def collate_wrapper_random(batch): | |
return BatchLoaderRandom(batch) | |