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Image-GS / gradio_app.py
Julien Blanchon
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 import os
import sys
import time
import threading
import argparse
import tempfile
import shutil
from typing import Generator, Optional, Tuple
import logging
import gradio as gr
import spaces
from huggingface_hub import hf_hub_download
import torch
from PIL import Image
# Add the project root to the path so we can import the modules
sys.path.append(os.path.dirname(os.path.abspath(__file__)))
from gradio_models import GradioGaussianSplatting2D, StreamingResults
from utils.misc_utils import load_cfg
from main import get_log_dir
class TrainingState:
"""Manages the state of training sessions"""
def __init__(self):
self.is_training = False
self.training_thread = None
self.model = None
self.temp_dir = None
self.results = StreamingResults()
def reset(self):
self.is_training = False
if self.temp_dir and os.path.exists(self.temp_dir):
shutil.rmtree(self.temp_dir)
self.temp_dir = None
self.results = StreamingResults()
# Global training state
training_state = TrainingState()
def ensure_models_available():
"""Download models from HuggingFace if they're not available locally"""
required_files = [
"models/emlnet/res_decoder.pth",
"models/emlnet/res_imagenet.pth",
"models/emlnet/res_places.pth",
"models/torch/checkpoints/alexnet-owt-7be5be79.pth",
]
# Check if all required files exist
all_files_exist = all(os.path.exists(file_path) for file_path in required_files)
if not all_files_exist:
print("πŸ“₯ Downloading model files from HuggingFace...")
try:
# Create models directory if it doesn't exist
os.makedirs("models", exist_ok=True)
# Download individual model files to ensure they end up in the right place
model_files_remote = [
"emlnet/res_decoder.pth",
"emlnet/res_imagenet.pth",
"emlnet/res_places.pth",
"torch/checkpoints/alexnet-owt-7be5be79.pth",
]
model_files_local = [
"models/emlnet/res_decoder.pth",
"models/emlnet/res_imagenet.pth",
"models/emlnet/res_places.pth",
"models/torch/checkpoints/alexnet-owt-7be5be79.pth",
]
for remote_file, local_file in zip(model_files_remote, model_files_local):
if not os.path.exists(local_file):
# Create directory structure
os.makedirs(os.path.dirname(local_file), exist_ok=True)
# Download the specific file
print(f"πŸ“₯ Downloading {remote_file} -> {local_file}...")
downloaded_path = hf_hub_download(
repo_id="blanchon/image-gs-models-utils",
filename=remote_file,
repo_type="model",
)
# Copy to the expected local path
shutil.copy2(downloaded_path, local_file)
print("βœ… Model files downloaded successfully!")
except Exception as e:
print(f"❌ Failed to download model files: {e}")
print("⚠️ The app may not work properly without these model files.")
else:
print("βœ… Model files are already available locally.")
# Initialize models and setup at module level for ZeroGPU packing
ensure_models_available()
torch.hub.set_dir("models/torch")
def create_args_from_config(
image_path: str,
exp_name: str,
num_gaussians: int,
quantize: bool,
pos_bits: int,
scale_bits: int,
rot_bits: int,
feat_bits: int,
init_mode: str,
init_random_ratio: float,
max_steps: int,
vis_gaussians: bool,
save_image_steps: int,
l1_loss_ratio: float,
l2_loss_ratio: float,
ssim_loss_ratio: float,
pos_lr: float,
scale_lr: float,
rot_lr: float,
feat_lr: float,
disable_lr_schedule: bool,
disable_prog_optim: bool,
) -> argparse.Namespace:
"""Create arguments object from Gradio inputs"""
# Load default config
parser = argparse.ArgumentParser()
parser = load_cfg(cfg_path="cfgs/default.yaml", parser=parser)
args = parser.parse_args([]) # Parse empty args to get defaults
# Override with user inputs
args.input_path = image_path
args.exp_name = exp_name
args.num_gaussians = num_gaussians
args.quantize = quantize
args.pos_bits = pos_bits
args.scale_bits = scale_bits
args.rot_bits = rot_bits
args.feat_bits = feat_bits
args.init_mode = init_mode
args.init_random_ratio = init_random_ratio
args.max_steps = max_steps
args.vis_gaussians = vis_gaussians
args.save_image_steps = save_image_steps
args.l1_loss_ratio = l1_loss_ratio
args.l2_loss_ratio = l2_loss_ratio
args.ssim_loss_ratio = ssim_loss_ratio
args.pos_lr = pos_lr
args.scale_lr = scale_lr
args.rot_lr = rot_lr
args.feat_lr = feat_lr
args.disable_lr_schedule = disable_lr_schedule
args.disable_prog_optim = disable_prog_optim
args.eval = False
# Set up logging directory
args.log_dir = get_log_dir(args)
return args
@spaces.GPU(duration=300) # Request GPU for up to 300 seconds (5 minutes)
def train_model(args: argparse.Namespace) -> None:
"""Training function that runs with ZeroGPU allocation"""
try:
# Create and train model with streaming results
training_state.model = GradioGaussianSplatting2D(args, training_state.results)
# Start training
training_state.model.optimize()
except Exception as e:
import traceback
training_state.results.training_logs.append(f"ERROR: {str(e)}")
training_state.results.training_logs.append(
f"TRACEBACK: {traceback.format_exc()}"
)
logging.error(f"Training failed: {str(e)}")
logging.error(f"TRACEBACK: {traceback.format_exc()}")
finally:
training_state.is_training = False
def start_training_and_stream(
image_file,
exp_name: str,
num_gaussians: int,
quantize: bool,
pos_bits: int,
scale_bits: int,
rot_bits: int,
feat_bits: int,
init_mode: str,
init_random_ratio: float,
max_steps: int,
vis_gaussians: bool,
save_image_steps: int,
l1_loss_ratio: float,
l2_loss_ratio: float,
ssim_loss_ratio: float,
pos_lr: float,
scale_lr: float,
rot_lr: float,
feat_lr: float,
disable_lr_schedule: bool,
disable_prog_optim: bool,
) -> Generator[
Tuple[
str,
str,
Optional[Image.Image], # initialization_map
Optional[Image.Image], # current_render
Optional[Image.Image], # current_gaussian_id
bool, # start_btn_interactive
bool, # stop_btn_interactive
],
None,
None,
]:
"""Start training and stream progress with images"""
if training_state.is_training:
yield (
"Training is already in progress!",
"",
None,
None,
None,
False, # start_btn disabled
True, # stop_btn enabled
)
return
if image_file is None:
yield (
"Please upload an image first!",
"",
None,
None,
None,
True, # start_btn enabled
False, # stop_btn disabled
)
return
try:
# Reset training state
training_state.reset()
# Create temporary directory for the uploaded image
training_state.temp_dir = tempfile.mkdtemp()
# Save uploaded image
image_path = os.path.join(training_state.temp_dir, "input_image.png")
image_file.save(image_path)
# Create args
args = create_args_from_config(
image_path=image_path,
exp_name=exp_name,
num_gaussians=num_gaussians,
quantize=quantize,
pos_bits=pos_bits,
scale_bits=scale_bits,
rot_bits=rot_bits,
feat_bits=feat_bits,
init_mode=init_mode,
init_random_ratio=init_random_ratio,
max_steps=max_steps,
vis_gaussians=vis_gaussians,
save_image_steps=save_image_steps,
l1_loss_ratio=l1_loss_ratio,
l2_loss_ratio=l2_loss_ratio,
ssim_loss_ratio=ssim_loss_ratio,
pos_lr=pos_lr,
scale_lr=scale_lr,
rot_lr=rot_lr,
feat_lr=feat_lr,
disable_lr_schedule=disable_lr_schedule,
disable_prog_optim=disable_prog_optim,
)
# Update data_root to use temp directory
args.data_root = training_state.temp_dir
args.input_path = "input_image.png"
# Start training in separate thread
training_state.is_training = True
training_state.training_thread = threading.Thread(
target=train_model, args=(args,)
)
training_state.training_thread.start()
# Initial yield
yield (
"Training started! Check the progress below.",
"Initializing training...",
None, # initialization_map
None, # current_render
None, # current_gaussian_id
False, # start_btn disabled
True, # stop_btn enabled
)
# Stream training progress
while training_state.is_training or not training_state.results.is_complete:
# Check if stop was requested
if (
not training_state.is_training
and training_state.training_thread
and training_state.training_thread.is_alive()
):
# Force stop the training thread if needed
training_state.results.training_logs.append(
"πŸ›‘ Training stopped by user request"
)
break
# Get training logs
if training_state.results.training_logs:
logs_text = "\n".join(training_state.results.training_logs)
# Add current metrics if available
if training_state.results.step > 0:
# Break if step is greater than total steps
if training_state.results.step > training_state.results.total_steps:
break
metrics = training_state.results.metrics
status_line = (
f"\nCurrent: Step {training_state.results.step}/{training_state.results.total_steps} | "
f"PSNR: {metrics['psnr']:.2f} | SSIM: {metrics['ssim']:.4f} | "
f"Loss: {metrics['loss']:.4f}"
)
logs_text += status_line
else:
logs_text = "Waiting for training to start..."
# Get current images
initialization_map = training_state.results.initialization_map
current_render = training_state.results.current_render
current_gaussian_id = training_state.results.current_gaussian_id
# Simple status based on training state
current_step = training_state.results.step
if training_state.results.is_complete:
status = "βœ… Training completed successfully!"
start_btn_interactive = True
stop_btn_interactive = False
elif not training_state.is_training:
status = "⏹️ Training stopped."
start_btn_interactive = True
stop_btn_interactive = False
else:
status = f"πŸ”„ Training in progress... Step {current_step}/{training_state.results.total_steps}"
start_btn_interactive = False
stop_btn_interactive = True
# Always yield, even if images haven't changed
yield (
status,
logs_text,
initialization_map,
current_render,
current_gaussian_id,
start_btn_interactive,
stop_btn_interactive,
)
# Stop if training is complete
if training_state.results.is_complete or not training_state.is_training:
break
if current_step > training_state.results.total_steps:
break
time.sleep(0.5) # Update more frequently for better responsiveness
except Exception as e:
training_state.reset()
yield (
f"Failed to start training: {str(e)}",
"",
None,
None,
None,
True, # start_btn enabled
False, # stop_btn disabled
)
def stop_training() -> str:
"""Stop the current training"""
if not training_state.is_training:
return "No training in progress."
training_state.is_training = False
training_state.results.training_logs.append(
"πŸ›‘ STOP: Training stop requested by user..."
)
# Set a flag in the model to stop training
if training_state.model:
training_state.model.stop_requested = True
return "Training stop requested. Will complete current step and stop."
def get_final_results() -> Tuple[Optional[Image.Image], Optional[str]]:
"""Get final training results"""
final_render = training_state.results.final_render
checkpoint_path = training_state.results.final_checkpoint_path
return final_render, checkpoint_path
def browse_step_results(
step: int,
) -> Tuple[Optional[Image.Image], Optional[Image.Image]]:
"""Browse results from a specific training step"""
if not training_state.results.is_complete:
return None, None
# Find the closest available step
available_steps = list(training_state.results.step_renders.keys())
if not available_steps:
return None, None
closest_step = min(available_steps, key=lambda x: abs(x - step))
render_img = training_state.results.step_renders.get(closest_step)
gaussian_id_img = training_state.results.step_gaussian_ids.get(closest_step)
return render_img, gaussian_id_img
def update_step_slider_after_training() -> gr.Slider:
"""Update step slider range and enable it after training completes"""
if not training_state.results.is_complete:
return gr.Slider(
minimum=0,
maximum=10000,
value=0,
step=100,
label="Browse Training Steps",
info="Training not complete yet",
interactive=False,
)
available_steps = list(training_state.results.step_renders.keys())
if not available_steps:
return gr.Slider(
minimum=0,
maximum=10000,
value=0,
step=100,
label="Browse Training Steps",
info="No training steps available",
interactive=False,
)
max_step = max(available_steps)
min_step = min(available_steps)
# Use the step size from save_image_steps if available, otherwise use difference between steps
if len(available_steps) > 1:
step_size = available_steps[1] - available_steps[0]
else:
step_size = 100
return gr.Slider(
minimum=min_step,
maximum=max_step,
value=max_step,
step=step_size,
label="Browse Training Steps",
info=f"Browse results from steps {min_step}-{max_step} (interactive)",
interactive=True,
)
# Create Gradio interface at top level (best practice for Spaces)
with gr.Blocks(title="Image-GS: 2D Gaussian Splatting", theme=gr.themes.Soft()) as demo:
gr.Markdown("""
# Image-GS: Content-Adaptive Image Representation via 2D Gaussians
Upload an image and configure parameters to train a 2D Gaussian Splatting representation.
""")
with gr.Row():
with gr.Column(scale=1):
gr.Markdown("## Configuration")
# Image upload
image_input = gr.Image(
label="Input Image",
type="pil",
height=300,
sources=["upload"],
show_label=True,
)
# Basic parameters
with gr.Group():
gr.Markdown("### Basic Parameters")
exp_name = gr.Textbox(
label="Experiment Name",
value="gradio_experiment",
info="Name for this training run",
)
num_gaussians = gr.Slider(
minimum=100,
maximum=50000,
value=10000,
step=1000,
label="Number of Gaussians",
info="Number of Gaussians (for compression rate control). More = higher quality but slower training",
)
max_steps = gr.Slider(
minimum=100,
maximum=20000,
value=10000,
step=100,
label="Maximum Training Steps",
info="Maximum number of optimization steps. Default: 10000",
)
# Quantization parameters
with gr.Group():
gr.Markdown("### Quantization")
quantize = gr.Checkbox(
label="Enable Quantization",
value=False,
info="Enable bit precision control of Gaussian parameters. Reduces memory usage.",
)
with gr.Row():
pos_bits = gr.Slider(
4,
32,
16,
step=1,
label="Position Bits",
info="Bit precision of individual coordinate dimension",
)
scale_bits = gr.Slider(
4,
32,
16,
step=1,
label="Scale Bits",
info="Bit precision of individual scale dimension",
)
with gr.Row():
rot_bits = gr.Slider(
4,
32,
16,
step=1,
label="Rotation Bits",
info="Bit precision of Gaussian orientation angle",
)
feat_bits = gr.Slider(
4,
32,
16,
step=1,
label="Feature Bits",
info="Bit precision of individual feature dimension",
)
# Initialization parameters
with gr.Group():
gr.Markdown("### Initialization")
init_mode = gr.Radio(
choices=["gradient", "saliency", "random"],
value="saliency",
label="Initialization Mode",
info="Gaussian position initialization mode. Gradient uses image gradients, saliency uses attention maps.",
)
init_random_ratio = gr.Slider(
minimum=0.0,
maximum=1.0,
value=0.3,
step=0.1,
label="Random Ratio",
info="Ratio of Gaussians with randomly initialized position (default: 0.3)",
)
# Advanced parameters (collapsible)
with gr.Accordion("Advanced Parameters", open=False):
# Loss parameters
gr.Markdown("#### Loss Weights")
with gr.Row():
l1_loss_ratio = gr.Slider(0.0, 2.0, 1.0, step=0.1, label="L1 Loss")
l2_loss_ratio = gr.Slider(0.0, 2.0, 0.0, step=0.1, label="L2 Loss")
ssim_loss_ratio = gr.Slider(
0.0, 1.0, 0.1, step=0.01, label="SSIM Loss"
)
# Learning rates
gr.Markdown("#### Learning Rates")
with gr.Row():
pos_lr = gr.Number(value=5e-4, label="Position LR", precision=6)
scale_lr = gr.Number(value=2e-3, label="Scale LR", precision=6)
with gr.Row():
rot_lr = gr.Number(value=2e-3, label="Rotation LR", precision=6)
feat_lr = gr.Number(value=5e-3, label="Feature LR", precision=6)
# Optimization options
gr.Markdown("#### Optimization")
disable_lr_schedule = gr.Checkbox(
label="Disable LR Schedule",
value=False,
info="Keep learning rate constant",
)
disable_prog_optim = gr.Checkbox(
label="Disable Progressive Optimization",
value=False,
info="Don't add Gaussians during training",
)
# Visualization parameters
with gr.Group():
gr.Markdown("### Visualization")
vis_gaussians = gr.Checkbox(
label="Visualize Gaussians",
value=True,
info="Visualize Gaussians during optimization (default: True)",
)
save_image_steps = gr.Slider(
minimum=200,
maximum=10000,
value=200,
step=100,
label="Save Image Every N Steps",
info="Frequency of rendering intermediate results during optimization (default: 100)",
)
# Control buttons
with gr.Row():
start_btn = gr.Button("Start Training", variant="primary", size="lg")
stop_btn = gr.Button("Stop Training", variant="stop", size="lg")
status_text = gr.Textbox(label="Status", interactive=False, lines=2)
with gr.Column(scale=2):
gr.Markdown("## Training Progress")
# Progress logs (streaming)
progress_logs = gr.Textbox(
label="Training Logs",
lines=10,
max_lines=15,
interactive=False,
autoscroll=True,
)
# Initial map (computed at start based on initialization mode)
gr.Markdown("### Initialization Map")
initialization_map = gr.Image(
label="Initialization Map",
type="pil",
height=200,
)
# Training images (streaming)
gr.Markdown("### Current Training Results")
with gr.Row():
current_render = gr.Image(
label="Current Render",
type="pil",
height=300,
show_label=True,
show_download_button=True,
)
current_gaussian_id = gr.Image(
label="Gaussian ID",
type="pil",
height=300,
show_label=True,
show_download_button=True,
)
# Step slider for interactive browsing (will be updated dynamically)
step_slider = gr.Slider(
minimum=0,
maximum=10000,
value=0,
step=100,
label="Browse Training Steps",
info="Slide to view results from different training steps (disabled during training)",
interactive=False,
)
gr.Markdown("## Final Results")
with gr.Row():
final_render = gr.Image(label="Final Render", type="pil", height=300)
final_checkpoint = gr.File(label="Download Final Checkpoint (.pt)")
# Results buttons
with gr.Row():
results_btn = gr.Button("Load Final Results", size="lg")
enable_slider_btn = gr.Button(
"Enable Step Browsing", size="lg", variant="secondary"
)
# Event handlers
start_btn.click(
fn=start_training_and_stream,
inputs=[
image_input,
exp_name,
num_gaussians,
quantize,
pos_bits,
scale_bits,
rot_bits,
feat_bits,
init_mode,
init_random_ratio,
max_steps,
vis_gaussians,
save_image_steps,
l1_loss_ratio,
l2_loss_ratio,
ssim_loss_ratio,
pos_lr,
scale_lr,
rot_lr,
feat_lr,
disable_lr_schedule,
disable_prog_optim,
],
outputs=[
status_text,
progress_logs,
initialization_map,
current_render,
current_gaussian_id,
start_btn,
stop_btn,
],
)
stop_btn.click(fn=stop_training, outputs=status_text)
results_btn.click(fn=get_final_results, outputs=[final_render, final_checkpoint])
enable_slider_btn.click(fn=update_step_slider_after_training, outputs=[step_slider])
step_slider.change(
fn=browse_step_results,
inputs=[step_slider],
outputs=[current_render, current_gaussian_id],
)
if __name__ == "__main__":
demo.queue(max_size=20).launch(server_name="0.0.0.0", server_port=7860, share=False)