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import numpy as np | |
from PIL import Image, ImageDraw, ImageFont | |
import cv2 | |
from ultralytics import YOLO | |
from database import save_prediction_to_db | |
# Load YOLO models | |
try: | |
yolo_model_glaucoma = YOLO('best-glaucoma-seg.pt') | |
yolo_model_od = YOLO("best-glaucoma-od.pt") | |
print("YOLO models loaded successfully.") | |
except Exception as e: | |
print(f"Error loading YOLO models: {e}") | |
def calculate_area(mask): | |
area = np.sum(mask > 0.5) | |
print(f"Calculated area: {area}") | |
return area | |
def classify_ddls(rim_to_disc_ratio): | |
if rim_to_disc_ratio >= 0.5: | |
stage = 0 # Non Glaucomatous | |
elif 0.4 <= rim_to_disc_ratio < 0.5: | |
stage = 1 | |
elif 0.3 <= rim_to_disc_ratio < 0.4: | |
stage = 2 | |
elif 0.2 <= rim_to_disc_ratio < 0.3: | |
stage = 3 | |
elif 0.1 <= rim_to_disc_ratio < 0.2: | |
stage = 4 | |
elif 0.0 < rim_to_disc_ratio < 0.1: | |
stage = 5 | |
else: | |
stage = 6 | |
print(f"Classified DDLS stage: {stage}") | |
return stage | |
def add_watermark(image): | |
try: | |
logo = Image.open('image-logo.png').convert("RGBA") | |
image = image.convert("RGBA") | |
# Resize logo | |
basewidth = 100 | |
wpercent = (basewidth / float(logo.size[0])) | |
hsize = int((float(wpercent) * logo.size[1])) | |
logo = logo.resize((basewidth, hsize), Image.LANCZOS) | |
# Position logo | |
position = (image.width - logo.width - 10, image.height - logo.height - 10) | |
# Composite image | |
transparent = Image.new('RGBA', (image.width, image.height), (0, 0, 0, 0)) | |
transparent.paste(image, (0, 0)) | |
transparent.paste(logo, position, mask=logo) | |
return transparent.convert("RGB") | |
except Exception as e: | |
print(f"Error adding watermark: {e}") | |
return image | |
def predict_and_visualize_glaucoma(image, mask_threshold=0.5): | |
try: | |
pil_image = Image.fromarray(image) | |
orig_size = pil_image.size | |
results = yolo_model_glaucoma(pil_image) | |
raw_response = str(results) | |
print(f"YOLO results: {raw_response}") | |
masked_image = np.array(pil_image) | |
mask_image = np.zeros_like(masked_image) | |
cup_mask, disk_mask = None, None | |
if len(results) > 0: | |
result = results[0] | |
if hasattr(result, 'masks') and result.masks is not None and len(result.masks) > 0: | |
for mask_data in result.masks.data: | |
mask = np.array(mask_data.cpu().squeeze().numpy()) | |
mask_resized = cv2.resize(mask, orig_size, interpolation=cv2.INTER_NEAREST) | |
if np.sum(mask_resized) > np.sum(disk_mask if disk_mask is not None else 0): | |
cup_mask = disk_mask | |
disk_mask = mask_resized | |
else: | |
cup_mask = mask_resized | |
if cup_mask is not None and disk_mask is not None: | |
area_cup = calculate_area(cup_mask) | |
area_disk = calculate_area(disk_mask) | |
rim_area = area_disk - area_cup | |
print(f"Area cup: {area_cup}, Area disk: {area_disk}, Rim area: {rim_area}") | |
rim_to_disc_ratio = rim_area / area_disk if area_disk > 0 else 0 | |
print(f"Rim to disc ratio: {rim_to_disc_ratio}") | |
ddls_stage = classify_ddls(rim_to_disc_ratio) | |
combined_image = np.array(pil_image) | |
# Create RGBA version of the original image | |
combined_image_rgba = cv2.cvtColor(combined_image, cv2.COLOR_RGB2RGBA) | |
# Create transparent masks | |
cup_mask_rgba = np.zeros_like(combined_image_rgba) | |
cup_mask_rgba[:, :, 0] = 0 # Red channel | |
cup_mask_rgba[:, :, 1] = 0 # Green channel | |
cup_mask_rgba[:, :, 2] = 255 # Blue channel | |
cup_mask_rgba[:, :, 3] = 128 # Alpha channel (50% transparency) | |
disk_mask_rgba = np.zeros_like(combined_image_rgba) | |
disk_mask_rgba[:, :, 0] = 255 # Red channel | |
disk_mask_rgba[:, :, 1] = 0 # Green channel | |
disk_mask_rgba[:, :, 2] = 0 # Blue channel | |
disk_mask_rgba[:, :, 3] = 128 # Alpha channel (50% transparency) | |
# Apply masks to the original image with transparency | |
cup_mask_indices = cup_mask > mask_threshold | |
disk_mask_indices = disk_mask > mask_threshold | |
combined_image_rgba[cup_mask_indices] = (0.5 * combined_image_rgba[cup_mask_indices] + 0.5 * cup_mask_rgba[cup_mask_indices]).astype(np.uint8) | |
combined_image_rgba[disk_mask_indices] = (0.5 * combined_image_rgba[disk_mask_indices] + 0.5 * disk_mask_rgba[disk_mask_indices]).astype(np.uint8) | |
# Convert to PIL image for drawing | |
combined_pil_image = Image.fromarray(combined_image_rgba) | |
# Add text to the image | |
draw = ImageDraw.Draw(combined_pil_image) | |
# Load a larger font (adjust the size as needed) | |
font_size = 48 # Example font size | |
try: | |
font = ImageFont.truetype("font.ttf", size=font_size) | |
except IOError: | |
font = ImageFont.load_default() | |
print("Error: cannot open resource, using default font.") | |
text = f"Area cup: {area_cup}\nArea disk: {area_disk}\nRim area: {rim_area}\nRim to disc ratio: {rim_to_disc_ratio:.2f}\nDDLS stage: {ddls_stage}" | |
text_x = 20 | |
text_y = 40 | |
draw.text((text_x, text_y), text, fill=(255, 255, 255, 255), font=font) | |
# Add watermark | |
combined_pil_image = add_watermark(combined_pil_image) | |
return np.array(combined_pil_image), area_cup, area_disk, rim_area, rim_to_disc_ratio, ddls_stage | |
print("No detected regions") | |
return np.zeros_like(image), 0, 0, 0, 0, "No detected regions" | |
except Exception as e: | |
print("Error:", e) | |
return np.zeros_like(image), 0, 0, 0, 0, str(e) | |
def combined_prediction_glaucoma(image, mask_threshold): | |
segmented_image, cup_area, disk_area, rim_area, rim_to_disc_ratio, ddls_stage = predict_and_visualize_glaucoma(image, mask_threshold) | |
print(f"Segmented image: {segmented_image.shape}") | |
print(f"Cup area: {cup_area}, Disk area: {disk_area}, Rim area: {rim_area}") | |
print(f"Rim to disc ratio: {rim_to_disc_ratio}, DDLS stage: {ddls_stage}") | |
return segmented_image, cup_area, disk_area, rim_area, rim_to_disc_ratio, ddls_stage | |
def submit_to_db(image, cup_area, disk_area, rim_area, rim_to_disc_ratio, ddls_stage): | |
try: | |
# Convert the image from numpy array to PIL image | |
pil_image = Image.fromarray(np.uint8(image)) | |
save_prediction_to_db(pil_image, cup_area, disk_area, rim_area, rim_to_disc_ratio, ddls_stage) | |
return "Values successfully saved to database.", "" | |
except Exception as e: | |
print(f"Error saving to database: {e}") | |
return f"Error saving to database: {e}", "" | |
def predict_image(input_image): | |
# Convert Gradio input image (PIL Image) to numpy array | |
image_np = np.array(input_image) | |
# Ensure the image is in the correct format | |
if len(image_np.shape) == 2: # grayscale to RGB | |
image_np = cv2.cvtColor(image_np, cv2.COLOR_GRAY2RGB) | |
elif image_np.shape[2] == 4: # RGBA to RGB | |
image_np = cv2.cvtColor(image_np, cv2.COLOR_RGBA2RGB) | |
# Perform prediction | |
results = yolo_model_od(image_np) | |
# Draw bounding boxes on the image | |
image_with_boxes = image_np.copy() | |
raw_predictions = [] | |
for result in results[0].boxes: | |
confidence = result.conf.item() # Convert tensor to standard Python type | |
label = "Glaucoma" if confidence > 0.5 else "Normal" # Set label based on confidence | |
xmin, ymin, xmax, ymax = map(int, result.xyxy[0]) | |
# Draw black rectangle as background for text | |
text = f'{label} {confidence:.2f}' | |
font_scale = 1.0 # Increased font scale | |
font_thickness = 2 # Increased font thickness | |
(w, h), baseline = cv2.getTextSize(text, cv2.FONT_HERSHEY_SIMPLEX, font_scale, font_thickness) | |
cv2.rectangle(image_with_boxes, (xmin, ymin - h - baseline), (xmin + w, ymin), (0, 0, 0), -1) | |
cv2.putText(image_with_boxes, text, (xmin, ymin - baseline), cv2.FONT_HERSHEY_SIMPLEX, font_scale, (255, 255, 255), font_thickness) | |
# Draw thicker bounding box | |
box_thickness = 3 # Increased box thickness | |
cv2.rectangle(image_with_boxes, (xmin, ymin), (xmax, ymax), (0, 255, 0), box_thickness) | |
raw_predictions.append(f"Label: {label}, Confidence: {confidence:.2f}, Box: [{xmin}, {ymin}, {xmax}, {ymax}]") | |
raw_predictions_str = "\n".join(raw_predictions) | |
# Add watermark to the final image with boxes | |
pil_image_with_boxes = Image.fromarray(image_with_boxes) | |
pil_image_with_boxes = add_watermark(pil_image_with_boxes) | |
image_with_boxes = np.array(pil_image_with_boxes) | |
return image_with_boxes, raw_predictions_str |