import os
import argparse
import numpy as np
from PIL import Image
import torch
import torchvision.transforms as T
from transformers import AutoTokenizer
import gradio as gr
from resnet50 import build_model
# from utils import generate_similiarity_map, post_process, load_tokenizer, build_transform_R50
from utils import generate_similiarity_map, get_transform, post_process, load_tokenizer, build_transform_R50
from utils import IMAGENET_MEAN, IMAGENET_STD
from internvl.train.dataset import dynamic_preprocess
from internvl.model.internvl_chat import InternVLChatModel
import spaces
# 模型配置
CHECKPOINTS = {
"TokenFD_4096_English_seg": "TongkunGuan/TokenFD_4096_English_seg",
"TokenFD_2048_Bilingual_seg": "TongkunGuan/TokenFD_2048_Bilingual_seg",
}
# 全局变量
HF_TOKEN = os.getenv("HF_TOKEN")
def load_model(check_type):
# device = torch.device("cuda" if torch.cuda.is_available() else "cpu")
device = torch.device("cuda")
if check_type == 'R50':
tokenizer = load_tokenizer('tokenizer_path')
model = build_model(argparse.Namespace()).eval()
model.load_state_dict(torch.load(CHECKPOINTS['R50'], map_location='cpu')['model'])
transform = build_transform_R50(normalize_type='imagenet')
elif check_type == 'R50_siglip':
tokenizer = load_tokenizer('tokenizer_path')
model = build_model(argparse.Namespace()).eval()
model.load_state_dict(torch.load(CHECKPOINTS['R50_siglip'], map_location='cpu')['model'])
transform = build_transform_R50(normalize_type='imagenet')
elif 'TokenFD' in check_type:
model_path = CHECKPOINTS[check_type]
tokenizer = AutoTokenizer.from_pretrained(model_path, trust_remote_code=True, use_fast=False, use_auth_token=HF_TOKEN)
# model = InternVLChatModel.from_pretrained(model_path, torch_dtype=torch.bfloat16).eval()
model = InternVLChatModel.from_pretrained(model_path, low_cpu_mem_usage=True, torch_dtype=torch.bfloat16 ,load_in_8bit=False, load_in_4bit=False).eval()
transform = get_transform(is_train=False, image_size=model.config.force_image_size)
return model.to(device), tokenizer, transform, device
def process_image(model, tokenizer, transform, device, check_type, image, text):
src_size = image.size
if 'TokenFD' in check_type:
images, target_ratio = dynamic_preprocess(image, min_num=1, max_num=12,
image_size=model.config.force_image_size,
use_thumbnail=model.config.use_thumbnail,
return_ratio=True)
pixel_values = torch.stack([transform(img) for img in images]).to(device)
else:
pixel_values = torch.stack([transform(image)]).to(device)
target_ratio = (1, 1)
# 文本处理
text_input = text
if text_input[0] in '!"#$%&\'()*+,-./0123456789:;<=>?@^_{|}~0123456789':
input_ids = tokenizer(text_input)['input_ids'][1:]
else:
input_ids = tokenizer(' '+text_input)['input_ids'][1:]
input_ids = torch.tensor(input_ids, device=device)
# 获取嵌入
with torch.no_grad():
if 'R50' in check_type:
text_embeds = model.language_embedding(input_ids)
else:
text_embeds = model.tok_embeddings(input_ids).clone()
vit_embeds, size1 = model.forward_tokenocr(pixel_values.to(torch.bfloat16).to(device))
print("vit_embeds",vit_embeds)
print("vit_embeds,shape",vit_embeds.shape)
print("target_ratio",target_ratio)
print("check_type",check_type)
vit_embeds, size2 = post_process(vit_embeds, target_ratio, check_type)
# 计算相似度
text_embeds = text_embeds / text_embeds.norm(dim=-1, keepdim=True)
vit_embeds = vit_embeds / vit_embeds.norm(dim=-1, keepdim=True)
similarity = text_embeds @ vit_embeds.T
resized_size = size1 if size1 is not None else size2
# print(f"text_embeds shape: {text_embeds.shape}, numel: {text_embeds.numel()}") # text_embeds shape: torch.Size([4, 2048]), numel: 8192
# print(f"vit_embeds shape: {vit_embeds.shape}, numel: {vit_embeds.numel()}") # vit_embeds shape: torch.Size([9728, 2048]), numel: 19922944
# print(f"similarity shape: {similarity.shape}, numel: {similarity.numel()}")# similarity shape: torch.Size([4, 9728]), numel: 38912
# 生成可视化
attn_map = similarity.reshape(len(text_embeds), resized_size[0], resized_size[1])
# attn_map = similarity.reshape(len(text_embeds), *target_ratio)
all_bpe_strings = [tokenizer.decode(input_id) for input_id in input_ids]
current_vis = generate_similiarity_map(images, attn_map,
[tokenizer.decode([i]) for i in input_ids],
[], target_ratio, src_size)
current_bpe = [tokenizer.decode([i]) for i in input_ids]
# current_bpe[-1] = 'Input text'
# current_bpe.append(text)
return image, current_vis, current_bpe
# 事件处理函数
# 上一项和下一项按钮
def update_index(direction, current_vis, current_bpe, current_index):
# 计算新的索引
new_index = max(0, min(current_index + direction, len(current_vis) - 1))
# 更新可视化内容
return (
current_vis[new_index],
format_bpe_display(current_bpe[new_index]),
new_index # 更新索引
)
def format_bpe_display(bpe):
# 使用HTML标签来设置字体大小、颜色,加粗,并居中
return f"Current BPE: {bpe}
"
# Gradio界面
with gr.Blocks(title="BPE Visualization Demo") as demo:
gr.Markdown("## BPE Visualization Demo - TokenFD基座模型能力可视化")
with gr.Row():
with gr.Column(scale=0.5):
model_type = gr.Dropdown(
choices=["TokenFD_4096_English_seg", "TokenFD_2048_Bilingual_seg"],
label="Select model type",
value="TokenFD_4096_English_seg" # 设置默认值为第一个选项
)
image_input = gr.Image(label="Upload images", type="pil")
text_input = gr.Textbox(label="Input text")
run_btn = gr.Button("RUN")
gr.Examples(
examples=[
[os.path.join("examples", "examples0.jpg"), "Veterans and Benefits"],
[os.path.join("examples", "examples1.jpg"), "Refreshers"],
[os.path.join("examples", "examples2.png"), "Vision Transformer"]
],
inputs=[image_input, text_input],
label="Sample input"
)
with gr.Column(scale=2):
gr.Markdown("If the input text is not included in the image, the attention map will show a lot of noise (the actual response value is very low), since we normalize the attention map according to the relative value.
")
with gr.Row():
orig_img = gr.Image(label="Original picture", interactive=False)
heatmap = gr.Image(label="BPE visualization", interactive=False)
with gr.Row() as controls:
prev_btn = gr.Button("⬅ Last", visible=False)
next_btn = gr.Button("⮕ Next", visible=False)
bpe_display = gr.Markdown("Current BPE: ")
current_vis_state = gr.State([])
current_bpe_state = gr.State([])
current_index_state = gr.State(0)
# 事件处理
@spaces.GPU
def on_run_clicked(model_type, image, text):
current_index = 0 # Reset index when new image is processed
image, current_vis, current_bpe = process_image(*load_model(model_type), model_type, image, text)
bpe_text = format_bpe_display(current_bpe)
print("current_vis",len(current_vis))
print("current_bpe",len(current_bpe))
# return image, current_vis[0],f"Current BPE: {current_bpe[0]}
", gr.update(visible=True), gr.update(visible=True)
return (
image,
current_vis[current_index],
format_bpe_display(current_bpe[current_index]),
gr.update(visible=True),
gr.update(visible=True),
current_vis, # 存储整个列表
current_bpe, # 存储整个列表
current_index # 存储当前索引
)
run_btn.click(
on_run_clicked,
inputs=[model_type, image_input, text_input],
outputs=[orig_img, heatmap, bpe_display, prev_btn, next_btn, current_vis_state, current_bpe_state, current_index_state]
)
prev_btn.click(
update_index,
inputs=[gr.State(-1), current_vis_state, current_bpe_state, current_index_state],
outputs=[heatmap, bpe_display, current_index_state]
)
next_btn.click(
update_index,
inputs=[gr.State(1), current_vis_state, current_bpe_state, current_index_state],
outputs=[heatmap, bpe_display, current_index_state]
)
if __name__ == "__main__":
demo.launch()