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LLM-Microscope-WAIC / app.py

matveymih

Update app.py

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	import gradio as gr
	import requests
	from PIL import Image
	import io
	from typing import Any, Tuple
	import os


	class Client:
	def __init__(self, server_url: str):
	self.server_url = server_url

	def send_request(self, task_name: str, model_name: str, text: str, normalization_type: str) -> Tuple[Any, str]:
	response = requests.post(
	self.server_url,
	json={
	"task_name": task_name,
	"model_name": model_name,
	"text": text,
	"normalization_type": normalization_type
	},
	timeout=60
	)
	if response.status_code == 200:
	response_data = response.json()
	img_data = bytes.fromhex(response_data["image"])
	img = Image.open(io.BytesIO(img_data))
	return img, "OK"
	else:
	return "Error, please retry", "Error: Could not get response from server"

	client = Client(f"http://{os.environ['SERVER']}/predict")

	def get_layerwise_nonlinearity(task_name: str, model_name: str, text: str, normalization_type: str) -> Tuple[Any, str]:
	return client.send_request(task_name, model_name, text, normalization_type)

	def update_output(task_name: str, model_name: str, text: str, normalization_type: str) -> Tuple[Any]:
	img, _ = get_layerwise_nonlinearity(task_name, model_name, text, normalization_type)
	return img

	def set_default(task_name: str) -> str:
	if task_name in ["Layer wise non-linearity", "Next-token prediction from intermediate representations", "Tokenwise loss without i-th layer"]:
	return "token-wise"
	return "global"

	def check_normalization(task_name: str, normalization_name) -> Tuple[str]:
	if task_name == "Contextualization measurement" and normalization_name == "token-wise":
	return "global"
	return normalization_name

	def update_description(task_name: str) -> str:
	descriptions = {
	"Layer wise non-linearity": "Non-linearity per layer: shows how complex each layer's transformation is. Red = more nonlinear.",
	"Next-token prediction from intermediate representations": "Layerwise token prediction: when does the model start guessing correctly?",
	"Contextualization measurement": "Context stored in each token: how well can the model reconstruct the previous context?",
	"Layerwise predictions (logit lens)": "Logit lens: what does each layer believe the next token should be?",
	"Tokenwise loss without i-th layer": "Layer ablation: how much does performance drop if a layer is removed?"
	}
	return descriptions.get(task_name, "ℹ️ No description available.")

	with gr.Blocks() as demo:
	# gr.Markdown("# 🔬 LLM-Microscope — Understanding Token Representations in Transformers")
	gr.Markdown("# 🔬 LLM-Microscope — A Look Inside the Black Box")
	gr.Markdown("Select a model, analysis mode, and input — then peek inside the black box of an LLM to see which layers matter most, which tokens carry the most memory, and how predictions evolve.")

	with gr.Row():
	model_selector = gr.Dropdown(
	choices=[
	"facebook/opt-1.3b",
	"TheBloke/Llama-2-7B-fp16",
	"Qwen/Qwen3-8B"
	],
	value="facebook/opt-1.3b",
	label="Select Model"
	)
	task_selector = gr.Dropdown(
	choices=[
	"Layer wise non-linearity",
	"Next-token prediction from intermediate representations",
	"Contextualization measurement",
	"Layerwise predictions (logit lens)",
	"Tokenwise loss without i-th layer"
	],
	value="Layer wise non-linearity",
	label="Select Mode"
	)
	normalization_selector = gr.Dropdown(
	choices=["global", "token-wise"],
	value="token-wise",
	label="Select Normalization"
	)

	task_description = gr.Markdown("ℹ️ Choose a mode to see what it does.")

	with gr.Column():
	text_message = gr.Textbox(label="Enter your input text:", value="I love to live my life")
	submit = gr.Button("Submit")
	box_for_plot = gr.Image(label="Visualization", type="pil")

	with gr.Accordion("📘 More Info and Explanation", open=False):
	gr.Markdown("""
	This heatmap shows how each token is processed across layers of a language model. Here's how to read it:

	- Rows: layers of the model (bottom = deeper)
	- Columns: input tokens
	- Colors: intensity of effect (depends on the selected metric)

	---

	### Metrics explained:

	- `Layer wise non-linearity`: how nonlinear the transformation is at each layer (red = more nonlinear).
	- `Next-token prediction from intermediate representations`: shows which layers begin to make good predictions.
	- `Contextualization measurement`: tokens with more context info get lower scores (green = more context).
	- `Layerwise predictions (logit lens)`: tracks how the model’s guesses evolve at each layer.
	- `Tokenwise loss without i-th layer`: shows how much each token depends on a specific layer. Red means performance drops if we skip this layer.

	Use this tool to peek inside the black box — it reveals which layers matter most, which tokens carry the most memory, and how LLMs evolve their predictions.

	---

	You can also use `llm-microscope` as a Python library to run these analyses on your own models and data.

	Just install it with: `pip install llm-microscope`

	More details provided in [GitHub repo](https://github.com/AIRI-Institute/LLM-Microscope).
	""")

	task_selector.change(fn=update_description, inputs=[task_selector], outputs=[task_description])
	task_selector.select(set_default, [task_selector], [normalization_selector])
	normalization_selector.select(check_normalization, [task_selector, normalization_selector], [normalization_selector])
	submit.click(
	fn=update_output,
	inputs=[task_selector, model_selector, text_message, normalization_selector],
	outputs=[box_for_plot]
	)

	if __name__ == "__main__":
	demo.launch(share=True, server_port=7860, server_name="0.0.0.0")