import spaces import gradio as gr from huggingface_hub import InferenceClient from torch import nn from transformers import AutoModel, AutoProcessor, AutoTokenizer, PreTrainedTokenizer, PreTrainedTokenizerFast, AutoModelForCausalLM from pathlib import Path import torch import torch.amp.autocast_mode from PIL import Image import os import torchvision.transforms.functional as TVF CLIP_PATH = "google/siglip-so400m-patch14-384" CHECKPOINT_PATH = Path("cgrkzexw-599808") TITLE = "

JoyCaption Alpha Two (2024-09-26a)

" CAPTION_TYPE_MAP = { "Descriptive": [ "Write a descriptive caption for this image in a formal tone.", "Write a descriptive caption for this image in a formal tone within {word_count} words.", "Write a {length} descriptive caption for this image in a formal tone.", ], "Descriptive (Informal)": [ "Write a descriptive caption for this image in a casual tone.", "Write a descriptive caption for this image in a casual tone within {word_count} words.", "Write a {length} descriptive caption for this image in a casual tone.", ], "Training Prompt": [ "Write a stable diffusion prompt for this image." "Write a stable diffusion prompt for this image within {word_count} words.", "Write a {length} stable diffusion prompt for this image.", ], "MidJourney": [ "Write a MidJourney prompt for this image.", "Write a MidJourney prompt for this image within {word_count} words.", "Write a {length} MidJourney prompt for this image.", ], "Booru tag list": [ "Write a list of Booru tags for this image.", "Write a list of Booru tags for this image within {word_count} words.", "Write a {length} list of Booru tags for this image.", ], "Booru-like tag list": [ "Write a list of Booru-like tags for this image.", "Write a list of Booru-like tags for this image within {word_count} words.", "Write a {length} list of Booru-like tags for this image.", ], "Art Critic": [ "Analyze this image like an art critic would with information about its composition, style, symbolism, the use of color, light, any artistic movement it might belong to, etc.", "Analyze this image like an art critic would with information about its composition, style, symbolism, the use of color, light, any artistic movement it might belong to, etc. Keep it within {word_count} words.", "Analyze this image like an art critic would with information about its composition, style, symbolism, the use of color, light, any artistic movement it might belong to, etc. Keep it {length}.", ], "Product Listing": [ "Write a caption for this image as though it were a product listing.", "Write a caption for this image as though it were a product listing. Keep it under {word_count} words.", "Write a {length} caption for this image as though it were a product listing.", ], "Social Media Post": [ "Write a caption for this image as if it were being used for a social media post.", "Write a caption for this image as if it were being used for a social media post. Limit the caption to {word_count} words.", "Write a {length} caption for this image as if it were being used for a social media post.", ], } HF_TOKEN = os.environ.get("HF_TOKEN", None) class ImageAdapter(nn.Module): def __init__(self, input_features: int, output_features: int, ln1: bool, pos_emb: bool, num_image_tokens: int, deep_extract: bool): super().__init__() self.deep_extract = deep_extract if self.deep_extract: input_features = input_features * 5 self.linear1 = nn.Linear(input_features, output_features) self.activation = nn.GELU() self.linear2 = nn.Linear(output_features, output_features) self.ln1 = nn.Identity() if not ln1 else nn.LayerNorm(input_features) self.pos_emb = None if not pos_emb else nn.Parameter(torch.zeros(num_image_tokens, input_features)) # Other tokens (<|image_start|>, <|image_end|>, <|eot_id|>) self.other_tokens = nn.Embedding(3, output_features) self.other_tokens.weight.data.normal_(mean=0.0, std=0.02) # Matches HF's implementation of llama3 def forward(self, vision_outputs: torch.Tensor): if self.deep_extract: x = torch.concat(( vision_outputs[-2], vision_outputs[3], vision_outputs[7], vision_outputs[13], vision_outputs[20], ), dim=-1) assert len(x.shape) == 3, f"Expected 3, got {len(x.shape)}" # batch, tokens, features assert x.shape[-1] == vision_outputs[-2].shape[-1] * 5, f"Expected {vision_outputs[-2].shape[-1] * 5}, got {x.shape[-1]}" else: x = vision_outputs[-2] x = self.ln1(x) if self.pos_emb is not None: assert x.shape[-2:] == self.pos_emb.shape, f"Expected {self.pos_emb.shape}, got {x.shape[-2:]}" x = x + self.pos_emb x = self.linear1(x) x = self.activation(x) x = self.linear2(x) # <|image_start|>, IMAGE, <|image_end|> other_tokens = self.other_tokens(torch.tensor([0, 1], device=self.other_tokens.weight.device).expand(x.shape[0], -1)) assert other_tokens.shape == (x.shape[0], 2, x.shape[2]), f"Expected {(x.shape[0], 2, x.shape[2])}, got {other_tokens.shape}" x = torch.cat((other_tokens[:, 0:1], x, other_tokens[:, 1:2]), dim=1) return x def get_eot_embedding(self): return self.other_tokens(torch.tensor([2], device=self.other_tokens.weight.device)).squeeze(0) # Load CLIP print("Loading CLIP") clip_processor = AutoProcessor.from_pretrained(CLIP_PATH) clip_model = AutoModel.from_pretrained(CLIP_PATH) clip_model = clip_model.vision_model assert (CHECKPOINT_PATH / "clip_model.pt").exists() print("Loading VLM's custom vision model") checkpoint = torch.load(CHECKPOINT_PATH / "clip_model.pt", map_location='cpu') checkpoint = {k.replace("_orig_mod.module.", ""): v for k, v in checkpoint.items()} clip_model.load_state_dict(checkpoint) del checkpoint clip_model.eval() clip_model.requires_grad_(False) clip_model.to("cuda") # Tokenizer print("Loading tokenizer") tokenizer = AutoTokenizer.from_pretrained(CHECKPOINT_PATH / "text_model", use_fast=True) assert isinstance(tokenizer, PreTrainedTokenizer) or isinstance(tokenizer, PreTrainedTokenizerFast), f"Tokenizer is of type {type(tokenizer)}" # LLM print("Loading LLM") print("Loading VLM's custom text model") text_model = AutoModelForCausalLM.from_pretrained(CHECKPOINT_PATH / "text_model", device_map=0, torch_dtype=torch.bfloat16) text_model.eval() # Image Adapter print("Loading image adapter") image_adapter = ImageAdapter(clip_model.config.hidden_size, text_model.config.hidden_size, False, False, 38, False) image_adapter.load_state_dict(torch.load(CHECKPOINT_PATH / "image_adapter.pt", map_location="cpu")) image_adapter.eval() image_adapter.to("cuda") @spaces.GPU() @torch.no_grad() def stream_chat(input_image: Image.Image, caption_type: str, caption_length: str | int, extra_options: list[str], name_input: str) -> tuple[str, str]: torch.cuda.empty_cache() # 'any' means no length specified length = None if caption_length == "any" else caption_length if isinstance(length, str): try: length = int(length) except ValueError: pass # Build prompt if length is None: map_idx = 0 elif isinstance(length, int): map_idx = 1 elif isinstance(length, str): map_idx = 2 else: raise ValueError(f"Invalid caption length: {length}") prompt_str = CAPTION_TYPE_MAP[caption_type][map_idx] # Add extra options if len(extra_options) > 0: prompt_str += " " + " ".join(extra_options) # For debugging print(f"Prompt: {prompt_str}") # Preprocess image # NOTE: I found the default processor for so400M to have worse results than just using PIL directly #image = clip_processor(images=input_image, return_tensors='pt').pixel_values image = input_image.resize((384, 384), Image.LANCZOS) pixel_values = TVF.pil_to_tensor(image).unsqueeze(0) / 255.0 pixel_values = TVF.normalize(pixel_values, [0.5], [0.5]) pixel_values = pixel_values.to('cuda') # Embed image # This results in Batch x Image Tokens x Features with torch.amp.autocast_mode.autocast('cuda', enabled=True): vision_outputs = clip_model(pixel_values=pixel_values, output_hidden_states=True) embedded_images = image_adapter(vision_outputs.hidden_states) embedded_images = embedded_images.to('cuda') # Build the conversation convo = [ { "role": "system", "content": "You are a helpful image captioner.", }, { "role": "user", "content": prompt_str, }, ] # Format the conversation convo_string = tokenizer.apply_chat_template(convo, tokenize = False, add_generation_prompt = True) assert isinstance(convo_string, str) # Tokenize the conversation # prompt_str is tokenized separately so we can do the calculations below convo_tokens = tokenizer.encode(convo_string, return_tensors="pt", add_special_tokens=False, truncation=False) prompt_tokens = tokenizer.encode(prompt_str, return_tensors="pt", add_special_tokens=False, truncation=False) assert isinstance(convo_tokens, torch.Tensor) and isinstance(prompt_tokens, torch.Tensor) convo_tokens = convo_tokens.squeeze(0) # Squeeze just to make the following easier prompt_tokens = prompt_tokens.squeeze(0) # Calculate where to inject the image eot_id_indices = (convo_tokens == tokenizer.convert_tokens_to_ids("<|eot_id|>")).nonzero(as_tuple=True)[0].tolist() assert len(eot_id_indices) == 2, f"Expected 2 <|eot_id|> tokens, got {len(eot_id_indices)}" preamble_len = eot_id_indices[1] - prompt_tokens.shape[0] # Number of tokens before the prompt # Embed the tokens convo_embeds = text_model.model.embed_tokens(convo_tokens.unsqueeze(0).to('cuda')) # Construct the input input_embeds = torch.cat([ convo_embeds[:, :preamble_len], # Part before the prompt embedded_images.to(dtype=convo_embeds.dtype), # Image convo_embeds[:, preamble_len:], # The prompt and anything after it ], dim=1).to('cuda') input_ids = torch.cat([ convo_tokens[:preamble_len].unsqueeze(0), torch.zeros((1, embedded_images.shape[1]), dtype=torch.long), # Dummy tokens for the image (TODO: Should probably use a special token here so as not to confuse any generation algorithms that might be inspecting the input) convo_tokens[preamble_len:].unsqueeze(0), ], dim=1).to('cuda') attention_mask = torch.ones_like(input_ids) # Debugging print(f"Input to model: {repr(tokenizer.decode(input_ids[0]))}") #generate_ids = text_model.generate(input_ids, inputs_embeds=inputs_embeds, attention_mask=attention_mask, max_new_tokens=300, do_sample=False, suppress_tokens=None) #generate_ids = text_model.generate(input_ids, inputs_embeds=inputs_embeds, attention_mask=attention_mask, max_new_tokens=300, do_sample=True, top_k=10, temperature=0.5, suppress_tokens=None) generate_ids = text_model.generate(input_ids, inputs_embeds=input_embeds, attention_mask=attention_mask, max_new_tokens=300, do_sample=True, suppress_tokens=None) # Uses the default which is temp=0.6, top_p=0.9 # Trim off the prompt generate_ids = generate_ids[:, input_ids.shape[1]:] if generate_ids[0][-1] == tokenizer.eos_token_id or generate_ids[0][-1] == tokenizer.convert_tokens_to_ids("<|eot_id|>"): generate_ids = generate_ids[:, :-1] caption = tokenizer.batch_decode(generate_ids, skip_special_tokens=False, clean_up_tokenization_spaces=False)[0] return prompt_str, caption.strip() with gr.Blocks() as demo: gr.HTML(TITLE) with gr.Row(): with gr.Column(): input_image = gr.Image(type="pil", label="Input Image") caption_type = gr.Dropdown( choices=["Descriptive", "Descriptive (Informal)", "Training Prompt", "MidJourney", "Booru tag list", "Booru-like tag list", "Art Critic", "Product Listing", "Social Media Post"], label="Caption Type", value="Descriptive", ) caption_length = gr.Dropdown( choices=["any", "very short", "short", "medium-length", "long", "very long"] + [str(i) for i in range(20, 261, 10)], label="Caption Length", value="long", ) extra_options = gr.CheckboxGroup( choices=[ "If there is a person/character in the image you must refer to them as {name}.", "Do NOT include information about people/characters that cannot be changed (like ethnicity, gender, etc), but do still include changeable attributes (like hair style).", "Include information about lighting.", "Include information about camera angle.", "Include information about whether there is a watermark or not.", "Include information about whether there are JPEG artifacts or not.", "If it is a photo you MUST include information about what camera was likely used and details such as aperture, shutter speed, ISO, etc.", "Do NOT include anything sexual; keep it PG.", "Do NOT mention the image's resolution.", "You MUST include information about the subjective aesthetic quality of the image from low to very high.", "Include information on the image's composition style, such as leading lines, rule of thirds, or symmetry.", "Do NOT mention any text that is in the image.", "Specify the depth of field and whether the background is in focus or blurred.", "If applicable, mention the likely use of artificial or natural lighting sources.", "Do NOT use any ambiguous language.", "Include whether the image is sfw, suggestive, or nsfw.", "ONLY describe the most important elements of the image." ], label="Extra Options" ) name_input = gr.Textbox(label="Person/Character Name (if applicable)") gr.Markdown("**Note:** Name input is only used if an Extra Option is selected that requires it.") run_button = gr.Button("Caption") with gr.Column(): output_prompt = gr.Textbox(label="Prompt") output_caption = gr.Textbox(label="Caption") run_button.click(fn=stream_chat, inputs=[input_image, caption_type, caption_length, extra_options, name_input], outputs=[output_caption, output_prompt]) if __name__ == "__main__": demo.launch()