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Running on Zero
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1913 | import gradio as gr
from gradio_bbox_annotator import BBoxAnnotator
from PIL import Image
import numpy as np
import torch
import os
import shutil
import time
import json
import uuid
from pathlib import Path
import tempfile
import zipfile
from skimage import measure
from matplotlib import cm
from glob import glob
from natsort import natsorted
from huggingface_hub import HfApi, upload_file
import spaces
from inference_seg import load_model as load_seg_model, run as run_seg
from inference_count import load_model as load_count_model, run as run_count
from inference_track import load_model as load_track_model, run as run_track
HF_TOKEN = os.getenv("HF_TOKEN")
DATASET_REPO = "phoebe777777/celltool_feedback"
print("===== clearing cache =====")
# cache_path = os.path.expanduser("~/.cache/")
cache_path = os.path.expanduser("~/.cache/huggingface/gradio")
if os.path.exists(cache_path):
try:
shutil.rmtree(cache_path)
# print("β
Deleted ~/.cache/")
print("β
Deleted ~/.cache/huggingface/gradio")
except:
pass
SEG_MODEL = None
SEG_DEVICE = torch.device("cpu")
COUNT_MODEL = None
COUNT_DEVICE = torch.device("cpu")
TRACK_MODEL = None
TRACK_DEVICE = torch.device("cpu")
def load_all_models():
global SEG_MODEL, SEG_DEVICE
global COUNT_MODEL, COUNT_DEVICE
global TRACK_MODEL, TRACK_DEVICE
print("\n" + "="*60)
print("π¦ Loading Segmentation Model")
print("="*60)
SEG_MODEL, SEG_DEVICE = load_seg_model(use_box=False)
print("\n" + "="*60)
print("π¦ Loading Counting Model")
print("="*60)
COUNT_MODEL, COUNT_DEVICE = load_count_model(use_box=False)
print("\n" + "="*60)
print("π¦ Loading Tracking Model")
print("="*60)
TRACK_MODEL, TRACK_DEVICE = load_track_model(use_box=False)
print("\n" + "="*60)
print("β
All Models Loaded Successfully")
print("="*60)
load_all_models()
DATASET_DIR = Path("solver_cache")
DATASET_DIR.mkdir(parents=True, exist_ok=True)
def save_feedback_to_hf(query_id, feedback_type, feedback_text=None, img_path=None, bboxes=None):
"""Save feedback to Hugging Face Dataset"""
if not HF_TOKEN:
print("β οΈ No HF_TOKEN found, using local storage")
save_feedback(query_id, feedback_type, feedback_text, img_path, bboxes)
return
feedback_data = {
"query_id": query_id,
"feedback_type": feedback_type,
"feedback_text": feedback_text,
"image_path": img_path,
"bboxes": str(bboxes), # 转为ε符串
"datetime": time.strftime("%Y-%m-%d %H:%M:%S"),
"timestamp": time.time()
}
try:
api = HfApi()
filename = f"feedback_{query_id}_{int(time.time())}.json"
with open(filename, 'w', encoding='utf-8') as f:
json.dump(feedback_data, f, indent=2, ensure_ascii=False)
api.upload_file(
path_or_fileobj=filename,
path_in_repo=f"data/{filename}",
repo_id=DATASET_REPO,
repo_type="dataset",
token=HF_TOKEN
)
os.remove(filename)
print(f"β
Feedback saved to HF Dataset: {DATASET_REPO}")
except Exception as e:
print(f"β οΈ Failed to save to HF Dataset: {e}")
save_feedback(query_id, feedback_type, feedback_text, img_path, bboxes)
def save_feedback(query_id, feedback_type, feedback_text=None, img_path=None, bboxes=None):
"""Save feedback to local JSON file"""
feedback_data = {
"query_id": query_id,
"feedback_type": feedback_type,
"feedback_text": feedback_text,
"image": img_path,
"bboxes": bboxes,
"datetime": time.strftime("%Y%m%d_%H%M%S")
}
feedback_file = DATASET_DIR / query_id / "feedback.json"
feedback_file.parent.mkdir(parents=True, exist_ok=True)
if feedback_file.exists():
with feedback_file.open("r") as f:
existing = json.load(f)
if not isinstance(existing, list):
existing = [existing]
existing.append(feedback_data)
feedback_data = existing
else:
feedback_data = [feedback_data]
with feedback_file.open("w") as f:
json.dump(feedback_data, f, indent=4, ensure_ascii=False)
def parse_first_bbox(bboxes):
"""Parse the first bounding box from the annotation input, supports dict or list format"""
if not bboxes:
return None
b = bboxes[0]
if isinstance(b, dict):
x, y = float(b.get("x", 0)), float(b.get("y", 0))
w, h = float(b.get("width", 0)), float(b.get("height", 0))
return x, y, x + w, y + h
if isinstance(b, (list, tuple)) and len(b) >= 4:
return float(b[0]), float(b[1]), float(b[2]), float(b[3])
return None
def parse_bboxes(bboxes):
"""Parse all bounding boxes from the annotation input"""
if not bboxes:
return None
result = []
for b in bboxes:
if isinstance(b, dict):
x, y = float(b.get("x", 0)), float(b.get("y", 0))
w, h = float(b.get("width", 0)), float(b.get("height", 0))
result.append([x, y, x + w, y + h])
elif isinstance(b, (list, tuple)) and len(b) >= 4:
result.append([float(b[0]), float(b[1]), float(b[2]), float(b[3])])
return result
def colorize_mask(mask: np.ndarray, num_colors: int = 512) -> np.ndarray:
"""Convert a 2D mask of instance IDs to a color image for visualization."""
def hsv_to_rgb(h, s, v):
i = int(h * 6.0)
f = h * 6.0 - i
i = i % 6
p = v * (1 - s)
q = v * (1 - f * s)
t = v * (1 - (1 - f) * s)
if i == 0: r, g, b = v, t, p
elif i == 1: r, g, b = q, v, p
elif i == 2: r, g, b = p, v, t
elif i == 3: r, g, b = p, q, v
elif i == 4: r, g, b = t, p, v
else: r, g, b = v, p, q
return int(r * 255), int(g * 255), int(b * 255)
palette = [(0, 0, 0)]
for i in range(1, num_colors):
h = (i % num_colors) / float(num_colors)
palette.append(hsv_to_rgb(h, 1.0, 0.95))
palette_arr = np.array(palette, dtype=np.uint8)
color_idx = mask % num_colors
return palette_arr[color_idx]
def render_seg_overlay(img_np, inst_mask, overlay_alpha):
"""Render segmentation overlay from cached image/mask."""
if img_np is None or inst_mask is None:
return None
overlay = img_np.copy()
alpha = float(np.clip(overlay_alpha, 0.0, 1.0))
for inst_id in np.unique(inst_mask):
if inst_id == 0:
continue
binary_mask = (inst_mask == inst_id).astype(np.uint8)
color = get_well_spaced_color(inst_id)
overlay[binary_mask == 1] = (1 - alpha) * overlay[binary_mask == 1] + alpha * color
contours = measure.find_contours(binary_mask, 0.5)
for contour in contours:
contour = contour.astype(np.int32)
valid_y = np.clip(contour[:, 0], 0, overlay.shape[0] - 1)
valid_x = np.clip(contour[:, 1], 0, overlay.shape[1] - 1)
overlay[valid_y, valid_x] = [1.0, 1.0, 0.0]
overlay = np.clip(overlay * 255.0, 0, 255).astype(np.uint8)
return Image.fromarray(overlay)
def render_count_overlay(img_np, density_normalized, overlay_alpha):
"""Render counting heatmap overlay from cached image/density."""
if img_np is None or density_normalized is None:
return None
alpha = float(np.clip(overlay_alpha, 0.0, 1.0))
cmap = cm.get_cmap("jet")
density_colored = cmap(density_normalized)[:, :, :3]
overlay = img_np.copy()
threshold = 0.01
significant_mask = density_normalized > threshold
overlay[significant_mask] = (1 - alpha) * overlay[significant_mask] + alpha * density_colored[significant_mask]
overlay = np.clip(overlay * 255.0, 0, 255).astype(np.uint8)
return Image.fromarray(overlay)
def update_seg_overlay_alpha(overlay_alpha, seg_vis_cache):
"""Live update segmentation visualization without rerunning inference."""
if not seg_vis_cache:
return None
return render_seg_overlay(seg_vis_cache.get("img_np"), seg_vis_cache.get("inst_mask"), overlay_alpha)
def update_count_overlay_alpha(overlay_alpha, count_vis_cache):
"""Live update counting visualization without rerunning inference."""
if not count_vis_cache:
return None
return render_count_overlay(count_vis_cache.get("img_np"), count_vis_cache.get("density_normalized"), overlay_alpha)
def update_tracking_overlay_alpha(overlay_alpha, track_vis_cache):
"""Regenerate tracking visualization at new opacity using cached outputs."""
if not track_vis_cache:
return None
tif_dir = track_vis_cache.get("tif_dir")
output_dir = track_vis_cache.get("output_dir")
valid_tif_files = track_vis_cache.get("valid_tif_files")
if not tif_dir or not output_dir or not valid_tif_files:
return None
try:
return create_tracking_visualization(
tif_dir=tif_dir,
output_dir=output_dir,
valid_tif_files=valid_tif_files,
overlay_alpha=overlay_alpha
)
except Exception as e:
print(f"β οΈ Failed to update tracking opacity: {e}")
return None
def cleanup_tracking_cache(track_vis_cache):
"""Delete cached tracking temp directories from the previous run."""
if not track_vis_cache:
return
for key in ["input_temp_dir", "output_dir"]:
path = track_vis_cache.get(key)
if path and os.path.isdir(path):
try:
shutil.rmtree(path)
except Exception:
pass
@spaces.GPU
def segment_with_choice(use_box_choice, annot_value, overlay_alpha):
"""Segmentation handler - supports bounding box, returns colorized overlay and original mask path"""
if annot_value is None or len(annot_value) < 1:
print("β No annotation input")
return None, None, {}
img_path = annot_value[0]
bboxes = annot_value[1] if len(annot_value) > 1 else []
print(f"πΌοΈ Image path: {img_path}")
box_array = None
if use_box_choice == "Yes" and bboxes:
box = parse_bboxes(bboxes)
if box:
box_array = box
print(f"π¦ Using bounding boxes: {box_array}")
try:
device = torch.device("cuda" if torch.cuda.is_available() else "cpu")
mask = run_seg(SEG_MODEL, img_path, box=box_array, device=device)
print("π mask shape:", mask.shape, "dtype:", mask.dtype)
except Exception as e:
print(f"β Inference failed: {str(e)}")
return None, None, {}
temp_mask_file = tempfile.NamedTemporaryFile(delete=False, suffix=".tif")
mask_img = Image.fromarray(mask.astype(np.uint16))
mask_img.save(temp_mask_file.name)
print(f"πΎ Original mask saved to: {temp_mask_file.name}")
try:
img = Image.open(img_path)
print("π· Image mode:", img.mode, "size:", img.size)
except Exception as e:
print(f"β Failed to open image: {e}")
return None, None, {}
try:
img_rgb = img.convert("RGB").resize(mask.shape[::-1], resample=Image.BILINEAR)
img_np = np.array(img_rgb, dtype=np.float32)
if img_np.max() > 1.5:
img_np = img_np / 255.0
except Exception as e:
print(f"β Error in image conversion/resizing: {e}")
return None, None, {}
mask_np = np.array(mask)
inst_mask = mask_np.astype(np.int32)
unique_ids = np.unique(inst_mask)
num_instances = len(unique_ids[unique_ids != 0])
if num_instances == 0:
print("β οΈ No instance found, returning dummy red image")
return Image.new("RGB", mask.shape[::-1], (255, 0, 0)), None, {}
overlay_img = render_seg_overlay(img_np, inst_mask, overlay_alpha)
seg_vis_cache = {"img_np": img_np, "inst_mask": inst_mask}
return overlay_img, temp_mask_file.name, seg_vis_cache
@spaces.GPU
def count_cells_handler(use_box_choice, annot_value, overlay_alpha):
"""Counting handler - supports bounding box, returns only density map"""
if annot_value is None or len(annot_value) < 1:
return None, None, "β οΈ Please provide an image.", {}
image_path = annot_value[0]
bboxes = annot_value[1] if len(annot_value) > 1 else []
print(f"πΌοΈ Image path: {image_path}")
box_array = None
if use_box_choice == "Yes" and bboxes:
box = parse_bboxes(bboxes)
if box:
box_array = box
print(f"π¦ Using bounding boxes: {box_array}")
try:
print(f"π’ Counting - Image: {image_path}")
device = torch.device("cuda" if torch.cuda.is_available() else "cpu")
result = run_count(
COUNT_MODEL,
image_path,
box=box_array,
device=device,
visualize=True
)
if 'error' in result:
return None, None, f"β Counting failed: {result['error']}", {}
count = result['count']
density_map = result['density_map']
temp_density_file = tempfile.NamedTemporaryFile(delete=False, suffix=".npy")
np.save(temp_density_file.name, density_map)
print(f"πΎ Density map saved to {temp_density_file.name}")
try:
img = Image.open(image_path)
print("π· Image mode:", img.mode, "size:", img.size)
except Exception as e:
print(f"β Failed to open image: {e}")
return None, None, f"β Failed to open image: {str(e)}", {}
try:
img_rgb = img.convert("RGB").resize(density_map.shape[::-1], resample=Image.BILINEAR)
img_np = np.array(img_rgb, dtype=np.float32)
img_np = (img_np - img_np.min()) / (img_np.max() - img_np.min() + 1e-8)
if img_np.max() > 1.5:
img_np = img_np / 255.0
except Exception as e:
print(f"β Error in image conversion/resizing: {e}")
return None, None, f"β Error in image conversion/resizing: {str(e)}", {}
density_normalized = density_map.copy()
if density_normalized.max() > 0:
density_normalized = (density_normalized - density_normalized.min()) / (density_normalized.max() - density_normalized.min())
overlay_img = render_count_overlay(img_np, density_normalized, overlay_alpha)
result_text = f"β
Detected {round(count)} objects"
if use_box_choice == "Yes" and box_array:
result_text += f"\nπ¦ Using bounding box: {box_array}"
print(f"β
Counting done - Count: {count:.1f}")
count_vis_cache = {"img_np": img_np, "density_normalized": density_normalized}
return overlay_img, temp_density_file.name, result_text, count_vis_cache
except Exception as e:
print(f"β Counting error: {e}")
import traceback
traceback.print_exc()
return None, None, f"β Counting failed: {str(e)}", {}
def find_tif_dir(root_dir):
"""Recursively find the first directory containing .tif files"""
for dirpath, _, filenames in os.walk(root_dir):
if '__MACOSX' in dirpath:
continue
if any(f.lower().endswith('.tif') for f in filenames):
return dirpath
return None
def is_valid_tiff(filepath):
"""Check if a file is a valid TIFF image"""
try:
with Image.open(filepath) as img:
img.verify()
return True
except Exception as e:
return False
def find_valid_tif_dir(root_dir):
"""Recursively find the first directory containing valid .tif files"""
for dirpath, dirnames, filenames in os.walk(root_dir):
if '__MACOSX' in dirpath:
continue
potential_tifs = [
os.path.join(dirpath, f)
for f in filenames
if f.lower().endswith(('.tif', '.tiff')) and not f.startswith('._')
]
if not potential_tifs:
continue
valid_tifs = [f for f in potential_tifs if is_valid_tiff(f)]
if valid_tifs:
print(f"β
Found {len(valid_tifs)} valid TIFF files in: {dirpath}")
return dirpath
return None
def create_ctc_results_zip(output_dir):
"""
Create a ZIP file with CTC format results
Parameters:
-----------
output_dir : str
Directory containing tracking results (res_track.txt, etc.)
Returns:
--------
zip_path : str
Path to created ZIP file
"""
# Create temp directory for ZIP
temp_zip_dir = tempfile.mkdtemp()
zip_filename = f"tracking_results_{time.strftime('%Y%m%d_%H%M%S')}.zip"
zip_path = os.path.join(temp_zip_dir, zip_filename)
print(f"π¦ Creating results ZIP: {zip_path}")
# Create ZIP with all tracking results
with zipfile.ZipFile(zip_path, 'w', zipfile.ZIP_DEFLATED) as zipf:
# Add all files from output directory
for root, dirs, files in os.walk(output_dir):
for file in files:
file_path = os.path.join(root, file)
arcname = os.path.relpath(file_path, output_dir)
zipf.write(file_path, arcname)
print(f" π Added: {arcname}")
# Add a README with summary
readme_content = f"""Tracking Results Summary
========================
Generated: {time.strftime('%Y-%m-%d %H:%M:%S')}
Files:
------
- res_track.txt: CTC format tracking data
Format: track_id start_frame end_frame parent_id
- Segmentation masks
For more information on CTC format:
http://celltrackingchallenge.net/
"""
zipf.writestr("README.txt", readme_content)
print(f"β
ZIP created: {zip_path} ({os.path.getsize(zip_path) / 1024:.1f} KB)")
return zip_path
def get_well_spaced_color(track_id, num_colors=256):
"""Generate well-spaced colors, using contrasting colors for adjacent IDs"""
golden_ratio = 0.618033988749895
hue = (track_id * golden_ratio) % 1.0
import colorsys
rgb = colorsys.hsv_to_rgb(hue, 0.9, 0.95)
return np.array(rgb)
def extract_first_frame(tif_dir):
"""
Extract the first frame from a directory of TIF files
Returns:
--------
first_frame_path : str
Path to the first TIF frame
"""
tif_files = natsorted(glob(os.path.join(tif_dir, "*.tif")) +
glob(os.path.join(tif_dir, "*.tiff")))
valid_tif_files = [f for f in tif_files
if not os.path.basename(f).startswith('._') and is_valid_tiff(f)]
if valid_tif_files:
return valid_tif_files[0]
return None
def create_tracking_visualization(tif_dir, output_dir, valid_tif_files, overlay_alpha=0.3):
"""
Create an animated GIF/video showing tracked objects with consistent colors
Parameters:
-----------
tif_dir : str
Directory containing input TIF frames
output_dir : str
Directory containing tracking results (masks)
valid_tif_files : list
List of valid TIF file paths
Returns:
--------
video_path : str
Path to generated visualization (GIF or first frame)
"""
import numpy as np
from matplotlib import colormaps
from skimage import measure
import tifffile
# Look for tracking mask files in output directory
# Common CTC formats: man_track*.tif, mask*.tif, or numbered masks
mask_files = natsorted(glob(os.path.join(output_dir, "mask*.tif")) +
glob(os.path.join(output_dir, "man_track*.tif")) +
glob(os.path.join(output_dir, "*.tif")))
if not mask_files:
print("β οΈ No mask files found in output directory")
# Return first frame as fallback
return valid_tif_files[0]
print(f"π Found {len(mask_files)} mask files")
frames = []
alpha = float(np.clip(overlay_alpha, 0.0, 1.0)) # Transparency for overlay
# Process each frame
num_frames = min(len(valid_tif_files), len(mask_files))
for i in range(num_frames):
try:
# Load original image using tifffile (handles ZSTD compression)
try:
img_np = tifffile.imread(valid_tif_files[i])
# Normalize to [0, 1] range based on actual data type and values
if img_np.dtype == np.uint8:
img_np = img_np.astype(np.float32) / 255.0
elif img_np.dtype == np.uint16:
# Normalize uint16 to [0, 1] using actual min/max
img_min, img_max = img_np.min(), img_np.max()
if img_max > img_min:
img_np = (img_np.astype(np.float32) - img_min) / (img_max - img_min)
else:
img_np = img_np.astype(np.float32) / 65535.0
else:
# For float or other types, normalize based on actual range
img_np = img_np.astype(np.float32)
img_min, img_max = img_np.min(), img_np.max()
if img_max > img_min:
img_np = (img_np - img_min) / (img_max - img_min)
else:
img_np = np.clip(img_np, 0, 1)
# Convert to RGB if grayscale
if img_np.ndim == 2:
img_np = np.stack([img_np]*3, axis=-1)
img_np = img_np.astype(np.float32)
if img_np.max() > 1.5:
img_np = img_np / 255.0
except Exception as e:
print(f"β οΈ Error loading image frame {i}: {e}")
# Fallback to PIL
img = Image.open(valid_tif_files[i]).convert("RGB")
img_np = np.array(img, dtype=np.float32) / 255.0
# Load tracking mask using tifffile (handles ZSTD compression)
try:
mask = tifffile.imread(mask_files[i])
except Exception as e:
print(f"β οΈ Error loading mask frame {i}: {e}")
# Fallback to PIL
mask = np.array(Image.open(mask_files[i]))
# Resize mask to match image if needed
if mask.shape[:2] != img_np.shape[:2]:
from scipy.ndimage import zoom
zoom_factors = [img_np.shape[0] / mask.shape[0], img_np.shape[1] / mask.shape[1]]
mask = zoom(mask, zoom_factors, order=0).astype(mask.dtype)
# Create overlay
overlay = img_np.copy()
# Get unique track IDs (excluding background 0)
track_ids = np.unique(mask)
track_ids = track_ids[track_ids != 0]
# Color each tracked object
for track_id in track_ids:
# Create binary mask for this track
binary_mask = (mask == track_id)
# Get consistent color for this track ID
# color = np.array(cmap(int(track_id) % 256)[:3])
color = get_well_spaced_color(int(track_id))
# Blend color onto image
overlay[binary_mask] = (1 - alpha) * overlay[binary_mask] + alpha * color
# Draw contours (optional, adds yellow boundaries)
try:
contours = measure.find_contours(binary_mask.astype(np.uint8), 0.5)
for contour in contours:
contour = contour.astype(np.int32)
valid_y = np.clip(contour[:, 0], 0, overlay.shape[0] - 1)
valid_x = np.clip(contour[:, 1], 0, overlay.shape[1] - 1)
overlay[valid_y, valid_x] = [1.0, 1.0, 0.0] # Yellow contour
except:
pass # Skip contours if they fail
# Convert to uint8
overlay_uint8 = np.clip(overlay * 255.0, 0, 255).astype(np.uint8)
frames.append(Image.fromarray(overlay_uint8))
if i % 10 == 0 or i == num_frames - 1:
print(f" πΈ Processed frame {i+1}/{num_frames}")
except Exception as e:
print(f"β οΈ Error processing frame {i}: {e}")
import traceback
traceback.print_exc()
continue
if not frames:
print("β οΈ No frames were processed successfully")
return valid_tif_files[0]
# Save as animated GIF
try:
temp_gif = tempfile.NamedTemporaryFile(delete=False, suffix=".gif")
frames[0].save(
temp_gif.name,
save_all=True,
append_images=frames[1:],
duration=200, # 200ms per frame = 5fps
loop=0
)
temp_gif.close() # Close the file handle
print(f"β
Created tracking visualization GIF: {temp_gif.name}")
print(f" Size: {os.path.getsize(temp_gif.name)} bytes, Frames: {len(frames)}")
return temp_gif.name
except Exception as e:
print(f"β οΈ Failed to create GIF: {e}")
import traceback
traceback.print_exc()
# Return first frame as static image fallback
try:
temp_img = tempfile.NamedTemporaryFile(delete=False, suffix=".png")
frames[0].save(temp_img.name)
temp_img.close()
return temp_img.name
except:
return valid_tif_files[0]
@spaces.GPU
def track_video_handler(use_box_choice, first_frame_annot, zip_file_obj, overlay_alpha, prev_track_vis_cache):
"""
Tracking handler - processes a ZIP of TIF frames, supports bounding box, returns visualization and results ZIP
Parameters:
-----------
use_box_choice : str
"Yes" or "No" - whether to use bounding box annotation for tracking
first_frame_annot : tuple or None
(image_path, bboxes) from BBoxAnnotator, only used if user annotated first frame
zip_file_obj : File
Uploaded ZIP file containing TIF sequence
"""
if zip_file_obj is None:
return None, "β οΈ Please upload a ZIP file containing video frames (.zip)", None, None, {}
cleanup_tracking_cache(prev_track_vis_cache)
temp_dir = None
output_temp_dir = None
try:
# Parse bounding box if provided
box_array = None
if use_box_choice == "Yes" and first_frame_annot is not None:
if isinstance(first_frame_annot, (list, tuple)) and len(first_frame_annot) > 1:
bboxes = first_frame_annot[1]
if bboxes:
box = parse_bboxes(bboxes)
if box:
box_array = box
print(f"π¦ Using bounding boxes: {box_array}")
# Extract input ZIP
temp_dir = tempfile.mkdtemp()
print(f"\nπ¦ Extracting to temporary directory: {temp_dir}")
with zipfile.ZipFile(zip_file_obj.name, 'r') as zip_ref:
extracted_count = 0
skipped_count = 0
for member in zip_ref.namelist():
basename = os.path.basename(member)
if ('__MACOSX' in member or
basename.startswith('._') or
basename.startswith('.DS_Store') or
member.endswith('/')):
skipped_count += 1
continue
try:
zip_ref.extract(member, temp_dir)
extracted_count += 1
if basename.lower().endswith(('.tif', '.tiff')):
print(f"π Extracted TIFF: {basename}")
except Exception as e:
print(f"β οΈ Failed to extract {member}: {e}")
print(f"\nπ Extracted: {extracted_count} files, Skipped: {skipped_count} files")
# Find valid TIFF directory
tif_dir = find_valid_tif_dir(temp_dir)
if tif_dir is None:
return None, "β Did not find valid TIF directory", None, None, {}
# Validate TIFF files
tif_files = natsorted(glob(os.path.join(tif_dir, "*.tif")) +
glob(os.path.join(tif_dir, "*.tiff")))
valid_tif_files = [f for f in tif_files
if not os.path.basename(f).startswith('._') and is_valid_tiff(f)]
if len(valid_tif_files) == 0:
return None, "β Did not find valid TIF files", None, None, {}
print(f"π Using {len(valid_tif_files)} TIF files")
# Store paths for later visualization
first_frame_path = valid_tif_files[0]
# Create temporary output directory for CTC results
output_temp_dir = tempfile.mkdtemp()
print(f"πΎ CTC-format results will be saved to: {output_temp_dir}")
# Run tracking with optional bounding box
device = torch.device("cuda" if torch.cuda.is_available() else "cpu")
result = run_track(
TRACK_MODEL,
video_dir=tif_dir,
box=box_array, # Pass bounding box if specified
device=device,
output_dir=output_temp_dir
)
if 'error' in result:
return None, f"β Tracking failed: {result['error']}", None, None, {}
# Create visualization video of tracked objects
print("\n㪠Creating tracking visualization...")
try:
tracking_video = create_tracking_visualization(
tif_dir,
output_temp_dir,
valid_tif_files,
overlay_alpha=overlay_alpha
)
except Exception as e:
print(f"β οΈ Failed to create visualization: {e}")
import traceback
traceback.print_exc()
# Fallback to first frame if visualization fails
try:
tracking_video = Image.open(first_frame_path)
except:
tracking_video = None
# Create downloadable ZIP with results
try:
results_zip = create_ctc_results_zip(output_temp_dir)
except Exception as e:
print(f"β οΈ Failed to create ZIP: {e}")
results_zip = None
bbox_info = ""
if box_array:
bbox_info = f"\nπ² Using bounding box: [{box_array[0][0]}, {box_array[0][1]}, {box_array[0][2]}, {box_array[0][3]}]"
result_text = f"""β
Tracking completed!
πΌοΈ Processed frames: {len(valid_tif_files)}{bbox_info}
π₯ Click the button below to download CTC-format results
The results include:
- res_track.txt (CTC-format tracking data)
- Other tracking-related files
- README.txt (Results description)
"""
if use_box_choice == "Yes" and box_array:
result_text += f"\nπ¦ Using bounding box: {box_array}"
print(f"\nβ
Tracking completed")
track_vis_cache = {
"tif_dir": tif_dir,
"valid_tif_files": valid_tif_files,
"output_dir": output_temp_dir,
"input_temp_dir": temp_dir,
}
return results_zip, result_text, gr.update(visible=True), tracking_video, track_vis_cache
except zipfile.BadZipFile:
return None, "β Not a valid ZIP file", None, None, {}
except Exception as e:
import traceback
traceback.print_exc()
# Clean up on error
for d in [temp_dir, output_temp_dir]:
if d:
try:
shutil.rmtree(d)
except:
pass
return None, f"β Tracking failed: {str(e)}", None, None, {}
# ===== Example Images =====
example_images_seg = [f for f in glob("example_imgs/seg/*")]
example_images_cnt = [f for f in glob("example_imgs/cnt/*")]
example_tracking_zips = [f for f in glob("example_imgs/tra/*.zip")]
# ===== Gradio UI =====
CSS = """
/* ββ Layout ββββββββββββββββββββββββββββββββββββββββββββ */
.gradio-container {
max-width: 1380px !important;
margin: 0 auto !important;
font-family: 'Inter', 'Segoe UI', system-ui, sans-serif !important;
}
/* ββ Header markdown polish βββββββββββββββββββββββββββββ */
.gradio-container .prose h1 {
font-size: 2rem !important;
font-weight: 700 !important;
color: #1e293b !important;
letter-spacing: -0.5px !important;
margin-bottom: 10px !important;
}
.gradio-container .prose h3 {
font-size: 1rem !important;
font-weight: 600 !important;
color: #0284c7 !important;
margin-top: 14px !important;
margin-bottom: 4px !important;
}
.gradio-container .prose p {
margin-top: 4px !important;
margin-bottom: 6px !important;
color: #475569 !important;
line-height: 1.7 !important;
}
.gradio-container .prose ul,
.gradio-container .prose ol {
margin-top: 4px !important;
margin-bottom: 6px !important;
}
.gradio-container .prose li {
color: #475569 !important;
line-height: 1.7 !important;
}
/* ββ Top-level header section βββββββββββββββββββββββββββ */
.gradio-container > .gap > .prose:first-child {
background: linear-gradient(135deg, #f0f9ff 0%, #e0f2fe 50%, #f0fdf4 100%) !important;
border: 1px solid #bae6fd !important;
border-radius: 16px !important;
padding: 28px 36px !important;
margin-bottom: 20px !important;
box-shadow: 0 4px 20px rgba(14,165,233,0.08) !important;
}
/* ββ Tabs ββββββββββββββββββββββββββββββββββββββββββββββ */
.tabs > .tab-nav {
border-bottom: 2px solid #e2e8f0 !important;
margin-bottom: 20px !important;
gap: 4px !important;
}
.tabs button {
font-size: 15px !important;
font-weight: 600 !important;
padding: 11px 24px !important;
border-radius: 8px 8px 0 0 !important;
color: #64748b !important;
transition: color 0.15s, background 0.15s !important;
}
.tabs button:hover {
color: #0ea5e9 !important;
background: #f0f9ff !important;
}
.tabs button.selected {
color: #0284c7 !important;
border-bottom: 3px solid #0284c7 !important;
background: transparent !important;
}
/* ββ Buttons βββββββββββββββββββββββββββββββββββββββββββ */
button.primary {
background: linear-gradient(135deg, #0284c7 0%, #0ea5e9 100%) !important;
border: none !important;
border-radius: 10px !important;
color: #fff !important;
font-weight: 600 !important;
font-size: 15px !important;
box-shadow: 0 3px 12px rgba(14,165,233,0.35) !important;
transition: transform 0.12s ease, box-shadow 0.15s ease !important;
}
button.primary:hover {
transform: translateY(-2px) !important;
box-shadow: 0 6px 20px rgba(14,165,233,0.45) !important;
}
button.secondary {
border-radius: 10px !important;
font-weight: 500 !important;
border: 1.5px solid #cbd5e1 !important;
color: #475569 !important;
transition: border-color 0.12s, color 0.12s, background 0.12s !important;
}
button.secondary:hover {
border-color: #94a3b8 !important;
color: #1e293b !important;
background: #f8fafc !important;
}
/* ββ Blocks and panels βββββββββββββββββββββββββββββββββ */
.gradio-container .block { border-radius: 14px !important; }
.gradio-container .gr-form,
.gradio-container .gr-box,
.gradio-container .gr-panel {
border-radius: 14px !important;
border-color: #e2e8f0 !important;
}
/* ββ Labels ββββββββββββββββββββββββββββββββββββββββββββ */
label { font-weight: 500 !important; color: #374151 !important; }
/* ββ Image output ββββββββββββββββββββββββββββββββββββββ */
.uniform-height {
height: 480px !important;
display: flex !important;
align-items: center !important;
justify-content: center !important;
border-radius: 12px !important;
background: #f8fafc !important;
}
.uniform-height img, .uniform-height canvas {
max-height: 480px !important;
object-fit: contain !important;
}
/* ββ Density map output ββββββββββββββββββββββββββββββββ */
#density_map_output { height: 480px !important; }
#density_map_output .image-container { height: 480px !important; }
#density_map_output img {
height: 460px !important;
width: auto !important;
max-width: 95% !important;
object-fit: contain !important;
}
/* ββ Tab content description markdown βββββββββββββββββ */
.tabitem .prose h2 {
font-size: 1.3rem !important;
font-weight: 700 !important;
color: #1e293b !important;
margin-top: 0 !important;
margin-bottom: 10px !important;
padding-bottom: 8px !important;
border-bottom: 2px solid #e0f2fe !important;
}
.tabitem .prose:nth-child(2) {
background: #f8fafc !important;
border: 1px solid #e2e8f0 !important;
border-radius: 10px !important;
padding: 12px 18px !important;
margin-bottom: 16px !important;
}
.tabitem .prose:nth-child(2) p,
.tabitem .prose:nth-child(2) li {
font-size: 0.91rem !important;
color: #64748b !important;
}
.tabitem .prose:nth-child(2) strong {
color: #0f172a !important;
}
/* ββββββββββββββββββββββββββββββββββββββββββββββββββββββββ
DARK MODE (.dark is added to <html> by Gradio)
ββββββββββββββββββββββββββββββββββββββββββββββββββββββββ */
/* ββ Header text βββββββββββββββββββββββββββββββββββββββ */
.dark .gradio-container .prose h1 {
color: #e2e8f0 !important;
}
.dark .gradio-container .prose h3 {
color: #38bdf8 !important;
}
.dark .gradio-container .prose p,
.dark .gradio-container .prose li {
color: #94a3b8 !important;
}
/* ββ Top-level header card βββββββββββββββββββββββββββββ */
.dark .gradio-container > .gap > .prose:first-child {
background: linear-gradient(135deg, #0c1a2e 0%, #0f2942 50%, #0d1f12 100%) !important;
border-color: #1e3a5f !important;
box-shadow: 0 4px 20px rgba(0,0,0,0.4) !important;
}
/* ββ Tabs ββββββββββββββββββββββββββββββββββββββββββββββ */
.dark .tabs > .tab-nav {
border-bottom-color: #334155 !important;
}
.dark .tabs button {
color: #94a3b8 !important;
}
.dark .tabs button:hover {
color: #38bdf8 !important;
background: rgba(56,189,248,0.08) !important;
}
.dark .tabs button.selected {
color: #38bdf8 !important;
border-bottom-color: #38bdf8 !important;
}
/* ββ Buttons βββββββββββββββββββββββββββββββββββββββββββ */
.dark button.secondary {
border-color: #475569 !important;
color: #94a3b8 !important;
background: transparent !important;
}
.dark button.secondary:hover {
border-color: #64748b !important;
color: #e2e8f0 !important;
background: rgba(255,255,255,0.05) !important;
}
/* ββ Blocks / panels βββββββββββββββββββββββββββββββββββ */
.dark .gradio-container .gr-form,
.dark .gradio-container .gr-box,
.dark .gradio-container .gr-panel {
border-color: #334155 !important;
}
/* ββ Labels ββββββββββββββββββββββββββββββββββββββββββββ */
.dark label {
color: #cbd5e1 !important;
}
/* ββ Image output area βββββββββββββββββββββββββββββββββ */
.dark .uniform-height {
background: #1e293b !important;
}
/* ββ Tab content markdown ββββββββββββββββββββββββββββββ */
.dark .tabitem .prose h2 {
color: #e2e8f0 !important;
border-bottom-color: #1e3a5f !important;
}
.dark .tabitem .prose:nth-child(2) {
background: #1e293b !important;
border-color: #334155 !important;
}
.dark .tabitem .prose:nth-child(2) p,
.dark .tabitem .prose:nth-child(2) li {
color: #94a3b8 !important;
}
.dark .tabitem .prose:nth-child(2) strong {
color: #e2e8f0 !important;
}
"""
with gr.Blocks(
title="Microscopy Analysis Suite",
theme=gr.themes.Soft(
primary_hue=gr.themes.colors.sky,
secondary_hue=gr.themes.colors.slate,
neutral_hue=gr.themes.colors.slate,
font=gr.themes.GoogleFont("Inter"),
),
css=CSS,
) as demo:
gr.Markdown(
"""
# π¬ MicroscopyMatching: Microscopy Image Analysis Suite
### Supporting three key tasks:
- π¨ **Segmentation**: Instance segmentation of microscopic objects
- π’ **Counting**: Counting microscopic objects based on density maps
- π¬ **Tracking**: Tracking microscopic objects in video sequences
### π‘ Technical Details:
**MicroscopyMatching** - A general-purpose microscopy image analysis toolkit based on pre-trained Latent Diffusion Model
### π Note:
This project is currently available with usage limits for research trial use and feedback collection. Please note that response speed may vary depending on GPU allocation queues. We plan to release a free public version in the future. We are actively improving the toolkit and greatly appreciate your feedback!
"""
)
# ε
¨ε±ηΆζ
current_query_id = gr.State(str(uuid.uuid4()))
user_uploaded_examples = gr.State(example_images_seg.copy())
seg_vis_state = gr.State({})
count_vis_state = gr.State({})
track_vis_state = gr.State({})
with gr.Tabs():
# ===== Tab 1: Segmentation =====
with gr.Tab("π¨ Segmentation"):
gr.Markdown("## Instance Segmentation of Microscopic Objects")
gr.Markdown(
"""
**Instructions:**
1. Upload an image or select an example image (supports various formats: .png, .jpg, .tif)
2. (Optional) Specify a target object with a bounding box and select "Yes", or click "Run Segmentation" directly
3. Click "Run Segmentation"
4. View the segmentation results (you can adjust the overlay opacity by sliding the opacity bar below the visualization), download the original predicted mask (.tif format); if needed, click "Clear Selection" to choose a new image
π€ Rate and submit feedback to help us improve the model!
"""
)
with gr.Row():
with gr.Column(scale=1):
annotator = BBoxAnnotator(
label="πΌοΈ Upload Image (Optional: Provide a Bounding Box)",
categories=["cell"],
)
# Example Images Gallery
example_gallery = gr.Gallery(
label="π Example Image Gallery",
columns=len(example_images_seg),
rows=1,
height=120,
object_fit="cover",
show_download_button=False
)
with gr.Row():
use_box_radio = gr.Radio(
choices=["Yes", "No"],
value="No",
label="π² Specify Bounding Box?"
)
with gr.Row():
run_seg_btn = gr.Button("βΆοΈ Run Segmentation", variant="primary", size="lg")
clear_btn = gr.Button("π Clear Selection", variant="secondary")
# Upload Example Image
image_uploader = gr.Image(
label="β Upload New Example Image to Gallery",
type="filepath"
)
with gr.Column(scale=2):
seg_output = gr.Image(
type="pil",
label="πΈ Segmentation Result",
elem_classes="uniform-height"
)
seg_alpha_slider = gr.Slider(
minimum=0.0,
maximum=1.0,
step=0.05,
value=0.5,
label="πͺ Overlay Opacity"
)
# Download Original Prediction
download_mask_btn = gr.File(
label="π₯ Download Original Prediction (.tif format)",
visible=True,
height=40,
)
# Satisfaction Rating
score_slider = gr.Slider(
minimum=1,
maximum=5,
step=1,
value=5,
label="π Satisfaction Rating (1-5)"
)
# Feedback Textbox
feedback_box = gr.Textbox(
placeholder="Please enter your feedback...",
lines=2,
label="π¬ Feedback"
)
# Submit Button
submit_feedback_btn = gr.Button("πΎ Submit Feedback", variant="secondary")
feedback_status = gr.Textbox(
label="β
Submission Status",
lines=1,
visible=False
)
# click event for segmentation
run_seg_btn.click(
fn=segment_with_choice,
inputs=[use_box_radio, annotator, seg_alpha_slider],
outputs=[seg_output, download_mask_btn, seg_vis_state]
)
seg_alpha_slider.input(
fn=update_seg_overlay_alpha,
inputs=[seg_alpha_slider, seg_vis_state],
outputs=seg_output
)
# click event for clear button
clear_btn.click(
fn=lambda: (None, {}),
inputs=None,
outputs=[annotator, seg_vis_state]
)
# init Gallery with example images
demo.load(
fn=lambda: example_images_seg.copy(),
outputs=example_gallery
)
# click event for image uploader
def add_to_gallery(img_path, current_imgs):
if not img_path:
return current_imgs
try:
if img_path not in current_imgs:
current_imgs.append(img_path)
return current_imgs
except:
return current_imgs
image_uploader.change(
fn=add_to_gallery,
inputs=[image_uploader, user_uploaded_examples],
outputs=user_uploaded_examples
).then(
fn=lambda imgs: imgs,
inputs=user_uploaded_examples,
outputs=example_gallery
)
# click event for Gallery selection
def load_from_gallery(evt: gr.SelectData, all_imgs):
if evt.index is not None and evt.index < len(all_imgs):
return all_imgs[evt.index]
return None
example_gallery.select(
fn=load_from_gallery,
inputs=user_uploaded_examples,
outputs=annotator
)
# click event for submitting feedback
def submit_user_feedback(query_id, score, comment, annot_val):
try:
img_path = annot_val[0] if annot_val and len(annot_val) > 0 else None
bboxes = annot_val[1] if annot_val and len(annot_val) > 1 else []
# save_feedback(
# query_id=query_id,
# feedback_type=f"score_{int(score)}",
# feedback_text=comment,
# img_path=img_path,
# bboxes=bboxes
# )
save_feedback_to_hf(
query_id=query_id,
feedback_type=f"score_{int(score)}",
feedback_text=comment,
img_path=img_path,
bboxes=bboxes
)
return "β
Feedback submitted, thank you!", gr.update(visible=True)
except Exception as e:
return f"β Submission failed: {str(e)}", gr.update(visible=True)
submit_feedback_btn.click(
fn=submit_user_feedback,
inputs=[current_query_id, score_slider, feedback_box, annotator],
outputs=[feedback_status, feedback_status]
)
# ===== Tab 2: Counting =====
with gr.Tab("π’ Counting"):
gr.Markdown("## Microscopy Object Counting Analysis")
gr.Markdown(
"""
**Usage Instructions:**
1. Upload an image or select an example image (supports multiple formats: .png, .jpg, .tif)
2. (Optional) Specify a target object with a bounding box and select "Yes", or click "Run Counting" directly
3. Click "Run Counting"
4. View the density map (you can adjust the density opacity by sliding the opacity bar below the visualization), download the original prediction (.npy format); if needed, click "Clear Selection" to choose a new image to run
π€ Rate and submit feedback to help us improve the model!
"""
)
with gr.Row():
with gr.Column(scale=1):
count_annotator = BBoxAnnotator(
label="πΌοΈ Upload Image (Optional: Provide a Bounding Box)",
categories=["cell"],
)
# Example gallery with "add" functionality
with gr.Row():
count_example_gallery = gr.Gallery(
label="π Example Image Gallery",
columns=len(example_images_cnt),
rows=1,
object_fit="cover",
height=120,
value=example_images_cnt.copy(), # Initialize with examples
show_download_button=False
)
with gr.Row():
count_use_box_radio = gr.Radio(
choices=["Yes", "No"],
value="No",
label="π² Specify Bounding Box?"
)
with gr.Row():
count_btn = gr.Button("βΆοΈ Run Counting", variant="primary", size="lg")
clear_btn = gr.Button("π Clear Selection", variant="secondary")
# Add button to upload new examples
with gr.Row():
count_image_uploader = gr.File(
label="β Add Example Image to Gallery",
file_types=["image"],
type="filepath"
)
with gr.Column(scale=2):
count_output = gr.Image(
label="πΈ Density Map",
type="filepath",
elem_id="density_map_output"
)
count_alpha_slider = gr.Slider(
minimum=0.0,
maximum=1.0,
step=0.05,
value=0.3,
label="πͺ Density Opacity"
)
count_status = gr.Textbox(
label="π Statistics",
lines=2
)
download_density_btn = gr.File(
label="π₯ Download Original Prediction (.npy format)",
visible=True
)
# Satisfaction rating
score_slider = gr.Slider(
minimum=1,
maximum=5,
step=1,
value=5,
label="π Satisfaction Rating (1-5)"
)
# Feedback textbox
feedback_box = gr.Textbox(
placeholder="Please enter your feedback...",
lines=2,
label="π¬ Feedback"
)
# Submit button
submit_feedback_btn = gr.Button("πΎ Submit Feedback", variant="secondary")
feedback_status = gr.Textbox(
label="β
Submission Status",
lines=1,
visible=False
)
# State for managing gallery images
count_user_examples = gr.State(example_images_cnt.copy())
# Function to add image to gallery
def add_to_count_gallery(new_img_file, current_imgs):
"""Add uploaded image to gallery"""
if new_img_file is None:
return current_imgs, current_imgs
try:
# Add new image path to list
if new_img_file not in current_imgs:
current_imgs.append(new_img_file)
print(f"β
Added image to gallery: {new_img_file}")
except Exception as e:
print(f"β οΈ Failed to add image: {e}")
return current_imgs, current_imgs
# When user uploads a new image file
count_image_uploader.upload(
fn=add_to_count_gallery,
inputs=[count_image_uploader, count_user_examples],
outputs=[count_user_examples, count_example_gallery]
)
# When user selects from gallery, load into annotator
def load_from_count_gallery(evt: gr.SelectData, all_imgs):
"""Load selected image from gallery into annotator"""
if evt.index is not None and evt.index < len(all_imgs):
selected_img = all_imgs[evt.index]
print(f"πΈ Loading image from gallery: {selected_img}")
return selected_img
return None
count_example_gallery.select(
fn=load_from_count_gallery,
inputs=count_user_examples,
outputs=count_annotator
)
# Run counting
count_btn.click(
fn=count_cells_handler,
inputs=[count_use_box_radio, count_annotator, count_alpha_slider],
outputs=[count_output, download_density_btn, count_status, count_vis_state]
)
count_alpha_slider.input(
fn=update_count_overlay_alpha,
inputs=[count_alpha_slider, count_vis_state],
outputs=count_output
)
# Clear selection
clear_btn.click(
fn=lambda: (None, {}),
inputs=None,
outputs=[count_annotator, count_vis_state]
)
# Submit feedback
def submit_user_feedback(query_id, score, comment, annot_val):
try:
img_path = annot_val[0] if annot_val and len(annot_val) > 0 else None
bboxes = annot_val[1] if annot_val and len(annot_val) > 1 else []
# save_feedback(
# query_id=query_id,
# feedback_type=f"score_{int(score)}",
# feedback_text=comment,
# img_path=img_path,
# bboxes=bboxes
# )
save_feedback_to_hf(
query_id=query_id,
feedback_type=f"score_{int(score)}",
feedback_text=comment,
img_path=img_path,
bboxes=bboxes
)
return "β
Feedback submitted successfully, thank you!", gr.update(visible=True)
except Exception as e:
return f"β Submission failed: {str(e)}", gr.update(visible=True)
submit_feedback_btn.click(
fn=submit_user_feedback,
inputs=[current_query_id, score_slider, feedback_box, annotator],
outputs=[feedback_status, feedback_status]
)
# ===== Tab 3: Tracking =====
with gr.Tab("π¬ Tracking"):
gr.Markdown("## Microscopy Object Video Tracking - Supports ZIP Upload")
gr.Markdown(
"""
**Instructions:**
1. Upload a ZIP file or select from the example library. The ZIP should contain a sequence of TIF images named in chronological order (e.g., t000.tif, t001.tif...)
2. (Optional) Specify a target object with a bounding box on the first frame and select "Yes", or click "Run Tracking" directly
3. Click "Run Tracking"
4. View the tracking results (you can adjust the overlay opacity by sliding the opacity bar below the visualization), download the CTC format results; if needed, click "Clear Selection" to choose a new ZIP file to run
π€ Rate and submit feedback to help us improve the model!
"""
)
with gr.Row():
with gr.Column(scale=1):
track_zip_upload = gr.File(
label="π¦ Upload Image Sequence in ZIP File",
file_types=[".zip"]
)
# First frame annotation for bounding box
track_first_frame_annotator = BBoxAnnotator(
label="πΌοΈ (Optional) First Frame Bounding Box Annotation",
categories=["cell"],
visible=False, # Hidden initially
)
# Example ZIP gallery
track_example_gallery = gr.Gallery(
label="π Example Video Gallery (Click to Select)",
columns=10,
rows=1,
height=120,
object_fit="contain",
show_download_button=False
)
with gr.Row():
track_use_box_radio = gr.Radio(
choices=["Yes", "No"],
value="No",
label="π² Specify Bounding Box?"
)
with gr.Row():
track_btn = gr.Button("βΆοΈ Run Tracking", variant="primary", size="lg")
clear_btn = gr.Button("π Clear Selection", variant="secondary")
# Add to gallery button
track_gallery_upload = gr.File(
label="β Add ZIP to Example Gallery",
file_types=[".zip"],
type="filepath"
)
with gr.Column(scale=2):
track_first_frame_preview = gr.Image(
label="πΈ Tracking Visualization",
type="filepath",
# height=400,
elem_classes="uniform-height",
interactive=False
)
track_alpha_slider = gr.Slider(
minimum=0.0,
maximum=1.0,
step=0.05,
value=0.3,
label="πͺ Overlay Opacity"
)
track_output = gr.Textbox(
label="π Tracking Information",
lines=8,
interactive=False
)
track_download = gr.File(
label="π₯ Download Tracking Results (CTC Format)",
visible=False
)
# Satisfaction rating
score_slider = gr.Slider(
minimum=1,
maximum=5,
step=1,
value=5,
label="π Satisfaction Rating (1-5)"
)
# Feedback textbox
feedback_box = gr.Textbox(
placeholder="Please enter your feedback...",
lines=2,
label="π¬ Feedback"
)
# Submit button
submit_feedback_btn = gr.Button("πΎ Submit Feedback", variant="secondary")
feedback_status = gr.Textbox(
label="β
Submission Status",
lines=1,
visible=False
)
# State for tracking examples
track_user_examples = gr.State(example_tracking_zips.copy())
# Function to get preview image from ZIP
def get_zip_preview(zip_path):
"""Extract first frame from ZIP for gallery preview"""
try:
temp_dir = tempfile.mkdtemp()
with zipfile.ZipFile(zip_path, 'r') as zip_ref:
for member in zip_ref.namelist():
basename = os.path.basename(member)
if ('__MACOSX' not in member and
not basename.startswith('._') and
basename.lower().endswith(('.tif', '.tiff', '.png', '.jpg'))):
zip_ref.extract(member, temp_dir)
extracted_path = os.path.join(temp_dir, member)
# Load and normalize for preview
import tifffile
import numpy as np
img_np = tifffile.imread(extracted_path)
if img_np.dtype == np.uint16:
img_min, img_max = img_np.min(), img_np.max()
if img_max > img_min:
img_np = ((img_np.astype(np.float32) - img_min) / (img_max - img_min) * 255).astype(np.uint8)
if img_np.ndim == 2:
img_np = np.stack([img_np]*3, axis=-1)
# Save preview
preview_path = tempfile.NamedTemporaryFile(delete=False, suffix=".png")
Image.fromarray(img_np).save(preview_path.name)
return preview_path.name
except:
pass
return None
# Initialize gallery with previews
def init_tracking_gallery():
"""Create preview images for ZIP examples"""
previews = []
for zip_path in example_tracking_zips:
if os.path.exists(zip_path):
preview = get_zip_preview(zip_path)
if preview:
previews.append(preview)
return previews
# Load gallery on startup
demo.load(
fn=init_tracking_gallery,
outputs=track_example_gallery
)
# Add ZIP to gallery
def add_zip_to_gallery(zip_path, current_zips):
if not zip_path:
return current_zips, track_example_gallery
try:
if zip_path not in current_zips:
current_zips.append(zip_path)
print(f"β
Added ZIP to gallery: {zip_path}")
# Regenerate previews
previews = []
for zp in current_zips:
preview = get_zip_preview(zp)
if preview:
previews.append(preview)
return current_zips, previews
except Exception as e:
print(f"β οΈ Error: {e}")
return current_zips, []
track_gallery_upload.upload(
fn=add_zip_to_gallery,
inputs=[track_gallery_upload, track_user_examples],
outputs=[track_user_examples, track_example_gallery]
)
# Select ZIP from gallery
def load_zip_from_gallery(evt: gr.SelectData, all_zips):
if evt.index is not None and evt.index < len(all_zips):
selected_zip = all_zips[evt.index]
print(f"π Selected ZIP from gallery: {selected_zip}")
return selected_zip
return None
track_example_gallery.select(
fn=load_zip_from_gallery,
inputs=track_user_examples,
outputs=track_zip_upload
)
# Load first frame when ZIP is uploaded
def load_first_frame_for_annotation(zip_file_obj):
'''Load and normalize first frame from ZIP for annotation'''
if zip_file_obj is None:
return None, gr.update(visible=False)
import tifffile
import numpy as np
try:
temp_dir = tempfile.mkdtemp()
with zipfile.ZipFile(zip_file_obj.name, 'r') as zip_ref:
for member in zip_ref.namelist():
basename = os.path.basename(member)
if ('__MACOSX' not in member and
not basename.startswith('._') and
basename.lower().endswith(('.tif', '.tiff'))):
zip_ref.extract(member, temp_dir)
tif_dir = find_valid_tif_dir(temp_dir)
if tif_dir:
first_frame = extract_first_frame(tif_dir)
if first_frame:
# Load and normalize the first frame
try:
img_np = tifffile.imread(first_frame)
# Normalize to [0, 255] uint8 range for display
if img_np.dtype == np.uint8:
pass # Already uint8
elif img_np.dtype == np.uint16:
# Normalize uint16 using actual min/max
img_min, img_max = img_np.min(), img_np.max()
if img_max > img_min:
img_np = ((img_np.astype(np.float32) - img_min) / (img_max - img_min) * 255).astype(np.uint8)
else:
img_np = (img_np.astype(np.float32) / 65535.0 * 255).astype(np.uint8)
else:
# Float or other types
img_np = img_np.astype(np.float32)
img_min, img_max = img_np.min(), img_np.max()
if img_max > img_min:
img_np = ((img_np - img_min) / (img_max - img_min) * 255).astype(np.uint8)
else:
img_np = np.clip(img_np * 255, 0, 255).astype(np.uint8)
# Convert to RGB if grayscale
if img_np.ndim == 2:
img_np = np.stack([img_np]*3, axis=-1)
elif img_np.ndim == 3 and img_np.shape[2] > 3:
img_np = img_np[:, :, :3]
# Save normalized image to temp file
temp_img = tempfile.NamedTemporaryFile(delete=False, suffix=".png")
Image.fromarray(img_np).save(temp_img.name)
print(f"β
Loaded and normalized first frame: {first_frame}")
print(f" Original dtype: {tifffile.imread(first_frame).dtype}")
print(f" Normalized to uint8 RGB for annotation")
return temp_img.name, gr.update(visible=True)
except Exception as e:
print(f"β οΈ Error normalizing first frame: {e}")
import traceback
traceback.print_exc()
# Fallback to original file
return first_frame, gr.update(visible=True)
except Exception as e:
print(f"β οΈ Error loading first frame: {e}")
import traceback
traceback.print_exc()
return None, gr.update(visible=False)
# Load first frame when ZIP is uploaded
track_zip_upload.change(
fn=load_first_frame_for_annotation,
inputs=track_zip_upload,
outputs=[track_first_frame_annotator, track_first_frame_annotator]
)
# Run tracking
track_btn.click(
fn=track_video_handler,
inputs=[track_use_box_radio, track_first_frame_annotator, track_zip_upload, track_alpha_slider, track_vis_state],
outputs=[track_download, track_output, track_download, track_first_frame_preview, track_vis_state]
)
track_alpha_slider.change(
fn=update_tracking_overlay_alpha,
inputs=[track_alpha_slider, track_vis_state],
outputs=track_first_frame_preview
)
# Clear selection
clear_btn.click(
fn=lambda: (None, {}),
inputs=None,
outputs=[track_first_frame_annotator, track_vis_state]
)
# Submit feedback
def submit_user_feedback(query_id, score, comment, annot_val):
try:
img_path = annot_val[0] if annot_val and len(annot_val) > 0 else None
bboxes = annot_val[1] if annot_val and len(annot_val) > 1 else []
# save_feedback(
# query_id=query_id,
# feedback_type=f"score_{int(score)}",
# feedback_text=comment,
# img_path=img_path,
# bboxes=bboxes
# )
save_feedback_to_hf(
query_id=query_id,
feedback_type=f"score_{int(score)}",
feedback_text=comment,
img_path=img_path,
bboxes=bboxes
)
return "β
Feedback submitted successfully, thank you!", gr.update(visible=True)
except Exception as e:
return f"β Submission failed: {str(e)}", gr.update(visible=True)
submit_feedback_btn.click(
fn=submit_user_feedback,
inputs=[current_query_id, score_slider, feedback_box, annotator],
outputs=[feedback_status, feedback_status]
)
if __name__ == "__main__":
demo.queue().launch(
server_name="0.0.0.0",
server_port=7860,
share=False,
ssr_mode=False,
show_error=True,
)
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