import os import re from typing import Dict, List import json import torch import numpy as np import random from PIL import Image from torchvision import transforms from transformers import AutoTokenizer from huggingface_hub import snapshot_download from OmniGen.utils import ( create_logger, update_ema, requires_grad, center_crop_arr, crop_arr, ) class OmniGenProcessor: def __init__(self, text_tokenizer, max_image_size: int=1024): self.text_tokenizer = text_tokenizer self.max_image_size = max_image_size self.image_transform = transforms.Compose([ transforms.Lambda(lambda pil_image: crop_arr(pil_image, max_image_size)), transforms.ToTensor(), transforms.Normalize(mean=[0.5, 0.5, 0.5], std=[0.5, 0.5, 0.5], inplace=True) ]) self.collator = OmniGenCollator() self.separate_collator = OmniGenSeparateCollator() @classmethod def from_pretrained(cls, model_name): if not os.path.exists(model_name): cache_folder = os.getenv('HF_HUB_CACHE') model_name = snapshot_download(repo_id=model_name, cache_dir=cache_folder, allow_patterns="*.json") text_tokenizer = AutoTokenizer.from_pretrained(model_name) return cls(text_tokenizer) def process_image(self, image): image = Image.open(image).convert('RGB') return self.image_transform(image) def process_multi_modal_prompt(self, text, input_images): text = self.add_prefix_instruction(text) if input_images is None or len(input_images) == 0: model_inputs = self.text_tokenizer(text) return {"input_ids": model_inputs.input_ids, "pixel_values": None, "image_sizes": None} pattern = r"<\|image_\d+\|>" prompt_chunks = [self.text_tokenizer(chunk).input_ids for chunk in re.split(pattern, text)] for i in range(1, len(prompt_chunks)): if prompt_chunks[i][0] == 1: prompt_chunks[i] = prompt_chunks[i][1:] image_tags = re.findall(pattern, text) image_ids = [int(s.split("|")[1].split("_")[-1]) for s in image_tags] unique_image_ids = sorted(list(set(image_ids))) assert unique_image_ids == list(range(1, len(unique_image_ids)+1)), f"image_ids must start from 1, and must be continuous int, e.g. [1, 2, 3], cannot be {unique_image_ids}" # total images must be the same as the number of image tags assert len(unique_image_ids) == len(input_images), f"total images must be the same as the number of image tags, got {len(unique_image_ids)} image tags and {len(input_images)} images" input_images = [input_images[x-1] for x in image_ids] all_input_ids = [] img_inx = [] idx = 0 for i in range(len(prompt_chunks)): all_input_ids.extend(prompt_chunks[i]) if i != len(prompt_chunks) -1: start_inx = len(all_input_ids) size = input_images[i].size(-2) * input_images[i].size(-1) // 16 // 16 img_inx.append([start_inx, start_inx+size]) all_input_ids.extend([0]*size) return {"input_ids": all_input_ids, "pixel_values": input_images, "image_sizes": img_inx} def add_prefix_instruction(self, prompt): user_prompt = '<|user|>\n' generation_prompt = 'Generate an image according to the following instructions\n' assistant_prompt = '<|assistant|>\n<|diffusion|>' prompt_suffix = "<|end|>\n" prompt = f"{user_prompt}{generation_prompt}{prompt}{prompt_suffix}{assistant_prompt}" return prompt def __call__(self, instructions: List[str], input_images: List[List[str]] = None, height: int = 1024, width: int = 1024, negative_prompt: str = "low quality, jpeg artifacts, ugly, duplicate, morbid, mutilated, extra fingers, mutated hands, poorly drawn hands, poorly drawn face, mutation, deformed, blurry, dehydrated, bad anatomy, bad proportions, extra limbs, cloned face, disfigured, gross proportions, malformed limbs, missing arms, missing legs, extra arms, extra legs, fused fingers, too many fingers.", use_img_cfg: bool = True, separate_cfg_input: bool = False, ) -> Dict: if input_images is None: use_img_cfg = False if isinstance(instructions, str): instructions = [instructions] input_images = [input_images] input_data = [] for i in range(len(instructions)): cur_instruction = instructions[i] cur_input_images = None if input_images is None else input_images[i] if cur_input_images is not None and len(cur_input_images) > 0: cur_input_images = [self.process_image(x) for x in cur_input_images] else: cur_input_images = None assert "<|image_1|>" not in cur_instruction mllm_input = self.process_multi_modal_prompt(cur_instruction, cur_input_images) neg_mllm_input, img_cfg_mllm_input = None, None neg_mllm_input = self.process_multi_modal_prompt(negative_prompt, None) if use_img_cfg: if cur_input_images is not None and len(cur_input_images) >= 1: img_cfg_prompt = [f"<|image_{i+1}|>" for i in range(len(cur_input_images))] img_cfg_mllm_input = self.process_multi_modal_prompt(" ".join(img_cfg_prompt), cur_input_images) else: img_cfg_mllm_input = neg_mllm_input input_data.append((mllm_input, neg_mllm_input, img_cfg_mllm_input, [height, width])) if separate_cfg_input: return self.separate_collator(input_data) return self.collator(input_data) class OmniGenCollator: def __init__(self, pad_token_id=2, hidden_size=3072): self.pad_token_id = pad_token_id self.hidden_size = hidden_size def create_position(self, attention_mask, num_tokens_for_output_images): position_ids = [] text_length = attention_mask.size(-1) img_length = max(num_tokens_for_output_images) for mask in attention_mask: temp_l = torch.sum(mask) temp_position = [0]*(text_length-temp_l) + [i for i in range(temp_l+img_length+1)] # we add a time embedding into the sequence, so add one more token position_ids.append(temp_position) return torch.LongTensor(position_ids) def create_mask(self, attention_mask, num_tokens_for_output_images): extended_mask = [] padding_images = [] text_length = attention_mask.size(-1) img_length = max(num_tokens_for_output_images) seq_len = text_length + img_length + 1 # we add a time embedding into the sequence, so add one more token inx = 0 for mask in attention_mask: temp_l = torch.sum(mask) pad_l = text_length - temp_l temp_mask = torch.tril(torch.ones(size=(temp_l+1, temp_l+1))) image_mask = torch.zeros(size=(temp_l+1, img_length)) temp_mask = torch.cat([temp_mask, image_mask], dim=-1) image_mask = torch.ones(size=(img_length, temp_l+img_length+1)) temp_mask = torch.cat([temp_mask, image_mask], dim=0) if pad_l > 0: pad_mask = torch.zeros(size=(temp_l+1+img_length, pad_l)) temp_mask = torch.cat([pad_mask, temp_mask], dim=-1) pad_mask = torch.ones(size=(pad_l, seq_len)) temp_mask = torch.cat([pad_mask, temp_mask], dim=0) true_img_length = num_tokens_for_output_images[inx] pad_img_length = img_length - true_img_length if pad_img_length > 0: temp_mask[:, -pad_img_length:] = 0 temp_padding_imgs = torch.zeros(size=(1, pad_img_length, self.hidden_size)) else: temp_padding_imgs = None extended_mask.append(temp_mask.unsqueeze(0)) padding_images.append(temp_padding_imgs) inx += 1 return torch.cat(extended_mask, dim=0), padding_images def adjust_attention_for_input_images(self, attention_mask, image_sizes): for b_inx in image_sizes.keys(): for start_inx, end_inx in image_sizes[b_inx]: attention_mask[b_inx][start_inx:end_inx, start_inx:end_inx] = 1 return attention_mask def pad_input_ids(self, input_ids, image_sizes): max_l = max([len(x) for x in input_ids]) padded_ids = [] attention_mask = [] new_image_sizes = [] for i in range(len(input_ids)): temp_ids = input_ids[i] temp_l = len(temp_ids) pad_l = max_l - temp_l if pad_l == 0: attention_mask.append([1]*max_l) padded_ids.append(temp_ids) else: attention_mask.append([0]*pad_l+[1]*temp_l) padded_ids.append([self.pad_token_id]*pad_l+temp_ids) if i in image_sizes: new_inx = [] for old_inx in image_sizes[i]: new_inx.append([x+pad_l for x in old_inx]) image_sizes[i] = new_inx return torch.LongTensor(padded_ids), torch.LongTensor(attention_mask), image_sizes def process_mllm_input(self, mllm_inputs, target_img_size): num_tokens_for_output_images = [] for img_size in target_img_size: num_tokens_for_output_images.append(img_size[0]*img_size[1]//16//16) pixel_values, image_sizes = [], {} b_inx = 0 for x in mllm_inputs: if x['pixel_values'] is not None: pixel_values.extend(x['pixel_values']) for size in x['image_sizes']: if b_inx not in image_sizes: image_sizes[b_inx] = [size] else: image_sizes[b_inx].append(size) b_inx += 1 pixel_values = [x.unsqueeze(0) for x in pixel_values] input_ids = [x['input_ids'] for x in mllm_inputs] padded_input_ids, attention_mask, image_sizes = self.pad_input_ids(input_ids, image_sizes) position_ids = self.create_position(attention_mask, num_tokens_for_output_images) attention_mask, padding_images = self.create_mask(attention_mask, num_tokens_for_output_images) attention_mask = self.adjust_attention_for_input_images(attention_mask, image_sizes) return padded_input_ids, position_ids, attention_mask, padding_images, pixel_values, image_sizes def __call__(self, features): mllm_inputs = [f[0] for f in features] cfg_mllm_inputs = [f[1] for f in features] img_cfg_mllm_input = [f[2] for f in features] target_img_size = [f[3] for f in features] if img_cfg_mllm_input[0] is not None: mllm_inputs = mllm_inputs + cfg_mllm_inputs + img_cfg_mllm_input target_img_size = target_img_size + target_img_size + target_img_size else: mllm_inputs = mllm_inputs + cfg_mllm_inputs target_img_size = target_img_size + target_img_size all_padded_input_ids, all_position_ids, all_attention_mask, all_padding_images, all_pixel_values, all_image_sizes = self.process_mllm_input(mllm_inputs, target_img_size) data = {"input_ids": all_padded_input_ids, "attention_mask": all_attention_mask, "position_ids": all_position_ids, "input_pixel_values": all_pixel_values, "input_image_sizes": all_image_sizes, "padding_images": all_padding_images, } return data class OmniGenSeparateCollator(OmniGenCollator): def __call__(self, features): mllm_inputs = [f[0] for f in features] cfg_mllm_inputs = [f[1] for f in features] img_cfg_mllm_input = [f[2] for f in features] target_img_size = [f[3] for f in features] all_padded_input_ids, all_attention_mask, all_position_ids, all_pixel_values, all_image_sizes, all_padding_images = [], [], [], [], [], [] padded_input_ids, position_ids, attention_mask, padding_images, pixel_values, image_sizes = self.process_mllm_input(mllm_inputs, target_img_size) all_padded_input_ids.append(padded_input_ids) all_attention_mask.append(attention_mask) all_position_ids.append(position_ids) all_pixel_values.append(pixel_values) all_image_sizes.append(image_sizes) all_padding_images.append(padding_images) if cfg_mllm_inputs[0] is not None: padded_input_ids, position_ids, attention_mask, padding_images, pixel_values, image_sizes = self.process_mllm_input(cfg_mllm_inputs, target_img_size) all_padded_input_ids.append(padded_input_ids) all_attention_mask.append(attention_mask) all_position_ids.append(position_ids) all_pixel_values.append(pixel_values) all_image_sizes.append(image_sizes) all_padding_images.append(padding_images) if img_cfg_mllm_input[0] is not None: padded_input_ids, position_ids, attention_mask, padding_images, pixel_values, image_sizes = self.process_mllm_input(img_cfg_mllm_input, target_img_size) all_padded_input_ids.append(padded_input_ids) all_attention_mask.append(attention_mask) all_position_ids.append(position_ids) all_pixel_values.append(pixel_values) all_image_sizes.append(image_sizes) all_padding_images.append(padding_images) data = {"input_ids": all_padded_input_ids, "attention_mask": all_attention_mask, "position_ids": all_position_ids, "input_pixel_values": all_pixel_values, "input_image_sizes": all_image_sizes, "padding_images": all_padding_images, } return data