from diffusers import CycleDiffusionPipeline, DDIMScheduler import gradio as gr import torch from PIL import Image import utils import ptp_utils import seq_aligner import torch.nn.functional as nnf from typing import Optional, Union, Tuple, List, Callable, Dict import abc LOW_RESOURCE = False MAX_NUM_WORDS = 77 is_colab = utils.is_google_colab() colab_instruction = "" if is_colab else """
You can skip the queue using Colab:
""" if True: model_id_or_path = "CompVis/stable-diffusion-v1-4" if is_colab: scheduler = DDIMScheduler.from_config(model_id_or_path, subfolder="scheduler") pipe = CycleDiffusionPipeline.from_pretrained(model_id_or_path, scheduler=scheduler) else: import streamlit as st scheduler = DDIMScheduler.from_config(model_id_or_path, use_auth_token=st.secrets["USER_TOKEN"], subfolder="scheduler") torch_dtype = torch.float16 if torch.cuda.is_available() else torch.float32 pipe = CycleDiffusionPipeline.from_pretrained(model_id_or_path, use_auth_token=st.secrets["USER_TOKEN"], scheduler=scheduler, torch_dtype=torch_dtype) tokenizer = pipe.tokenizer if torch.cuda.is_available(): pipe = pipe.to("cuda") device_print = "GPU ๐ฅ" if torch.cuda.is_available() else "CPU ๐ฅถ" device = "cuda" if torch.cuda.is_available() else "cpu" class LocalBlend: def __call__(self, x_t, attention_store): k = 1 maps = attention_store["down_cross"][2:4] + attention_store["up_cross"][:3] maps = [item.reshape(self.alpha_layers.shape[0], -1, 1, 16, 16, MAX_NUM_WORDS) for item in maps] maps = torch.cat(maps, dim=1) maps = (maps * self.alpha_layers).sum(-1).mean(1) mask = nnf.max_pool2d(maps, (k * 2 + 1, k * 2 + 1), (1, 1), padding=(k, k)) mask = nnf.interpolate(mask, size=(x_t.shape[2:])) mask = mask / mask.max(2, keepdims=True)[0].max(3, keepdims=True)[0] mask = mask.gt(self.threshold) mask = (mask[:1] + mask[1:]).to(x_t.dtype) x_t = x_t[:1] + mask * (x_t - x_t[:1]) return x_t def __init__(self, prompts: List[str], words: [List[List[str]]], threshold=.3): alpha_layers = torch.zeros(len(prompts), 1, 1, 1, 1, MAX_NUM_WORDS) for i, (prompt, words_) in enumerate(zip(prompts, words)): if type(words_) is str: words_ = [words_] for word in words_: ind = ptp_utils.get_word_inds(prompt, word, tokenizer) alpha_layers[i, :, :, :, :, ind] = 1 self.alpha_layers = alpha_layers.to(device).to(torch_dtype) self.threshold = threshold class AttentionControl(abc.ABC): def step_callback(self, x_t): return x_t def between_steps(self): return @property def num_uncond_att_layers(self): return self.num_att_layers if LOW_RESOURCE else 0 @abc.abstractmethod def forward(self, attn, is_cross: bool, place_in_unet: str): raise NotImplementedError def __call__(self, attn, is_cross: bool, place_in_unet: str): if self.cur_att_layer >= self.num_uncond_att_layers: if LOW_RESOURCE: attn = self.forward(attn, is_cross, place_in_unet) else: h = attn.shape[0] attn[h // 2:] = self.forward(attn[h // 2:], is_cross, place_in_unet) self.cur_att_layer += 1 if self.cur_att_layer == self.num_att_layers + self.num_uncond_att_layers: self.cur_att_layer = 0 self.cur_step += 1 self.between_steps() return attn def reset(self): self.cur_step = 0 self.cur_att_layer = 0 def __init__(self): self.cur_step = 0 self.num_att_layers = -1 self.cur_att_layer = 0 class EmptyControl(AttentionControl): def forward(self, attn, is_cross: bool, place_in_unet: str): return attn class AttentionStore(AttentionControl): @staticmethod def get_empty_store(): return {"down_cross": [], "mid_cross": [], "up_cross": [], "down_self": [], "mid_self": [], "up_self": []} def forward(self, attn, is_cross: bool, place_in_unet: str): key = f"{place_in_unet}_{'cross' if is_cross else 'self'}" if attn.shape[1] <= 32 ** 2: # avoid memory overhead self.step_store[key].append(attn) return attn def between_steps(self): if len(self.attention_store) == 0: self.attention_store = self.step_store else: for key in self.attention_store: for i in range(len(self.attention_store[key])): self.attention_store[key][i] += self.step_store[key][i] self.step_store = self.get_empty_store() def get_average_attention(self): average_attention = {key: [item / self.cur_step for item in self.attention_store[key]] for key in self.attention_store} return average_attention def reset(self): super(AttentionStore, self).reset() self.step_store = self.get_empty_store() self.attention_store = {} def __init__(self): super(AttentionStore, self).__init__() self.step_store = self.get_empty_store() self.attention_store = {} class AttentionControlEdit(AttentionStore, abc.ABC): def step_callback(self, x_t): if self.local_blend is not None: x_t = self.local_blend(x_t, self.attention_store) return x_t def replace_self_attention(self, attn_base, att_replace): if att_replace.shape[2] <= 16 ** 2: return attn_base.unsqueeze(0).expand(att_replace.shape[0], *attn_base.shape) else: return att_replace @abc.abstractmethod def replace_cross_attention(self, attn_base, att_replace): raise NotImplementedError def forward(self, attn, is_cross: bool, place_in_unet: str): super(AttentionControlEdit, self).forward(attn, is_cross, place_in_unet) if is_cross or (self.num_self_replace[0] <= self.cur_step < self.num_self_replace[1]): h = attn.shape[0] // self.batch_size attn = attn.reshape(self.batch_size, h, *attn.shape[1:]) attn_base, attn_repalce = attn[0], attn[1:] if is_cross: alpha_words = self.cross_replace_alpha[self.cur_step] attn_replace_new = self.replace_cross_attention(attn_base, attn_repalce) * alpha_words + (1 - alpha_words) * attn_repalce attn[1:] = attn_replace_new else: attn[1:] = self.replace_self_attention(attn_base, attn_repalce) attn = attn.reshape(self.batch_size * h, *attn.shape[2:]) return attn def __init__(self, prompts, num_steps: int, cross_replace_steps: Union[float, Tuple[float, float], Dict[str, Tuple[float, float]]], self_replace_steps: Union[float, Tuple[float, float]], local_blend: Optional[LocalBlend]): super(AttentionControlEdit, self).__init__() self.batch_size = len(prompts) self.cross_replace_alpha = ptp_utils.get_time_words_attention_alpha(prompts, num_steps, cross_replace_steps, tokenizer).to(device).to(torch_dtype) if type(self_replace_steps) is float: self_replace_steps = 0, self_replace_steps self.num_self_replace = int(num_steps * self_replace_steps[0]), int(num_steps * self_replace_steps[1]) self.local_blend = local_blend class AttentionReplace(AttentionControlEdit): def replace_cross_attention(self, attn_base, att_replace): return torch.einsum('hpw,bwn->bhpn', attn_base, self.mapper) def __init__(self, prompts, num_steps: int, cross_replace_steps: float, self_replace_steps: float, local_blend: Optional[LocalBlend] = None): super(AttentionReplace, self).__init__(prompts, num_steps, cross_replace_steps, self_replace_steps, local_blend) self.mapper = seq_aligner.get_replacement_mapper(prompts, tokenizer).to(device).to(torch_dtype) class AttentionRefine(AttentionControlEdit): def replace_cross_attention(self, attn_base, att_replace): attn_base_replace = attn_base[:, :, self.mapper].permute(2, 0, 1, 3) attn_replace = attn_base_replace * self.alphas + att_replace * (1 - self.alphas) return attn_replace def __init__(self, prompts, num_steps: int, cross_replace_steps: float, self_replace_steps: float, local_blend: Optional[LocalBlend] = None): super(AttentionRefine, self).__init__(prompts, num_steps, cross_replace_steps, self_replace_steps, local_blend) self.mapper, alphas = seq_aligner.get_refinement_mapper(prompts, tokenizer) self.mapper, alphas = self.mapper.to(device).to(torch_dtype), alphas.to(device).to(torch_dtype) self.alphas = alphas.reshape(alphas.shape[0], 1, 1, alphas.shape[1]) def get_equalizer(text: str, word_select: Union[int, Tuple[int, ...]], values: Union[List[float], Tuple[float, ...]]): if type(word_select) is int or type(word_select) is str: word_select = (word_select,) equalizer = torch.ones(len(values), 77) values = torch.tensor(values, dtype=torch_dtype) for word in word_select: inds = ptp_utils.get_word_inds(text, word, tokenizer) equalizer[:, inds] = values return equalizer def inference(source_prompt, target_prompt, source_guidance_scale=1, guidance_scale=5, num_inference_steps=100, width=512, height=512, seed=0, img=None, strength=0.7, cross_attention_control="None", cross_replace_steps=0.8, self_replace_steps=0.4): torch.manual_seed(seed) ratio = min(height / img.height, width / img.width) img = img.resize((int(img.width * ratio), int(img.height * ratio))) # create the CAC controller. if cross_attention_control == "Replace": controller = AttentionReplace([source_prompt, target_prompt], num_inference_steps, cross_replace_steps=cross_replace_steps, self_replace_steps=self_replace_steps, ) ptp_utils.register_attention_control(pipe, controller) elif cross_attention_control == "Refine": controller = AttentionRefine([source_prompt, target_prompt], num_inference_steps, cross_replace_steps=cross_replace_steps, self_replace_steps=self_replace_steps, ) ptp_utils.register_attention_control(pipe, controller) elif cross_attention_control == "None": controller = EmptyControl() ptp_utils.register_attention_control(pipe, controller) else: raise ValueError("Unknown cross_attention_control: {}".format(cross_attention_control)) results = pipe(prompt=target_prompt, source_prompt=source_prompt, init_image=img, num_inference_steps=num_inference_steps, eta=0.1, strength=strength, guidance_scale=guidance_scale, source_guidance_scale=source_guidance_scale, ) return replace_nsfw_images(results) def replace_nsfw_images(results): for i in range(len(results.images)): if results.nsfw_content_detected[i]: results.images[i] = Image.open("nsfw.png") return results.images[0] css = """.cycle-diffusion-div div{display:inline-flex;align-items:center;gap:.8rem;font-size:1.75rem}.cycle-diffusion-div div h1{font-weight:900;margin-bottom:7px}.cycle-diffusion-div p{margin-bottom:10px;font-size:94%}.cycle-diffusion-div p a{text-decoration:underline}.tabs{margin-top:0;margin-bottom:0}#gallery{min-height:20rem} """ with gr.Blocks(css=css) as demo: gr.HTML( f"""
Demo for CycleDiffusion with Stable Diffusion.
CycleDiffusion (๐ Paper link | ๐งจ Pipeline doc) is an image-to-image translation method that supports stochastic samplers for diffusion models.
We also support the combination of CycleDiffusion and Cross Attention Control (CAC | ๐ Paper link). CAC is a technique to transfer the attention map from the source prompt to the target prompt.
Quick start:
1. Click one row of Examples at the end of this page. It will fill all inputs needed.
2. Click the "Run CycleDiffusion" button.
{colab_instruction} Running on {device_print}{(" in a Google Colab." if is_colab else "")}
How to use:
1. Upload an image.
2. Enter the source and target prompts.
3. Select the source guidance scale (for "encoding") and the target guidance scale (for "decoding").
4. Select the strength (smaller strength means better content preservation).
5 (optional). Configurate Cross Attention Control options (e.g., CAC type, cross replace steps, self replace steps).
6 (optional). Configurate other options (e.g., image size, inference steps, random seed).
7. Click the "Run CycleDiffusion" button.
Notes:
1. CycleDiffusion is likely to fail when drastic changes are intended (e.g., changing a large black car to red).
2. The value of strength can be set larger when CAC is used.
3. If CAC type is "Replace", the source and target prompts should differ in only one token; otherwise, an error will be raised. This is why we deliberately make some grammar mistakes in Examples.
4. If CAC type is "Refine", the source prompt be a subsequence of the target prompt; otherwise, an error will be raised.
Runtimes:
1. 30s on A10G.
2. 90s on T4.