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SOC3242-01_Group_3_Interactive

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David Driscoll

Remove onnx, again

5c7b604 2 months ago

14.9 kB

	import gradio as gr
	import cv2
	import numpy as np
	import torch
	from torchvision import models, transforms
	from torchvision.models.detection import FasterRCNN_ResNet50_FPN_Weights
	from PIL import Image
	import mediapipe as mp
	from fer import FER # Facial emotion recognition
	# from transformers import AutoFeatureExtractor, AutoModel # (Unused now for facial recognition)

	# -----------------------------
	# Configuration
	# -----------------------------
	SKIP_RATE = 1 # For image processing, always run the analysis
	device = torch.device("cuda" if torch.cuda.is_available() else "cpu")
	DESIRED_SIZE = (640, 480)

	# -----------------------------
	# Global caches for overlay info and frame counters
	# -----------------------------
	posture_cache = {"landmarks": None, "text": "Initializing...", "counter": 0}
	emotion_cache = {"text": "Initializing...", "counter": 0}
	objects_cache = {"boxes": None, "text": "Initializing...", "object_list_text": "", "counter": 0}
	faces_cache = {"boxes": None, "text": "Initializing...", "counter": 0}

	# -----------------------------
	# Initialize Models and Helpers
	# -----------------------------
	# MediaPipe Pose, Face Detection, and Face Mesh
	mp_pose = mp.solutions.pose
	pose = mp_pose.Pose()
	mp_drawing = mp.solutions.drawing_utils

	mp_face_detection = mp.solutions.face_detection
	face_detection = mp_face_detection.FaceDetection(min_detection_confidence=0.5)

	# Object Detection using Faster R-CNN
	object_detection_model = models.detection.fasterrcnn_resnet50_fpn(
	weights=FasterRCNN_ResNet50_FPN_Weights.DEFAULT
	)
	object_detection_model.eval().to(device)
	obj_transform = transforms.Compose([transforms.ToTensor()])

	# Initialize the FER emotion detector (using the FER package)
	emotion_detector = FER(mtcnn=True)

	# Retrieve object categories from model weights metadata
	object_categories = FasterRCNN_ResNet50_FPN_Weights.DEFAULT.meta["categories"]

	# -----------------------------
	# Overlay Drawing Functions
	# -----------------------------
	def draw_posture_overlay(raw_frame, landmarks):
	for connection in mp_pose.POSE_CONNECTIONS:
	start_idx, end_idx = connection
	if start_idx < len(landmarks) and end_idx < len(landmarks):
	start_point = landmarks[start_idx]
	end_point = landmarks[end_idx]
	cv2.line(raw_frame, start_point, end_point, (50, 205, 50), 2)
	for (x, y) in landmarks:
	cv2.circle(raw_frame, (x, y), 4, (50, 205, 50), -1)
	return raw_frame

	def draw_boxes_overlay(raw_frame, boxes, color):
	for (x1, y1, x2, y2) in boxes:
	cv2.rectangle(raw_frame, (x1, y1), (x2, y2), color, 2)
	return raw_frame

	# -----------------------------
	# Heavy (Synchronous) Detection Functions
	# -----------------------------
	def compute_posture_overlay(image):
	frame_bgr = cv2.cvtColor(np.array(image), cv2.COLOR_RGB2BGR)
	h, w, _ = frame_bgr.shape
	frame_bgr_small = cv2.resize(frame_bgr, DESIRED_SIZE)
	small_h, small_w, _ = frame_bgr_small.shape
	frame_rgb_small = cv2.cvtColor(frame_bgr_small, cv2.COLOR_BGR2RGB)
	pose_results = pose.process(frame_rgb_small)
	if pose_results.pose_landmarks:
	landmarks = []
	for lm in pose_results.pose_landmarks.landmark:
	x = int(lm.x * small_w * (w / small_w))
	y = int(lm.y * small_h * (h / small_h))
	landmarks.append((x, y))
	text = "Posture detected"
	else:
	landmarks = []
	text = "No posture detected"
	return landmarks, text

	def compute_emotion_overlay(image):
	frame_bgr = cv2.cvtColor(np.array(image), cv2.COLOR_RGB2BGR)
	frame_bgr_small = cv2.resize(frame_bgr, DESIRED_SIZE)
	frame_rgb_small = cv2.cvtColor(frame_bgr_small, cv2.COLOR_BGR2RGB)
	emotions = emotion_detector.detect_emotions(frame_rgb_small)
	if emotions:
	top_emotion, score = max(emotions[0]["emotions"].items(), key=lambda x: x[1])
	text = f"{top_emotion} ({score:.2f})"
	else:
	text = "No face detected"
	return text

	def compute_objects_overlay(image):
	frame_bgr = cv2.cvtColor(np.array(image), cv2.COLOR_RGB2BGR)
	frame_bgr_small = cv2.resize(frame_bgr, DESIRED_SIZE)
	frame_rgb_small = cv2.cvtColor(frame_bgr_small, cv2.COLOR_BGR2RGB)
	image_pil = Image.fromarray(frame_rgb_small)
	img_tensor = obj_transform(image_pil).to(device)
	with torch.no_grad():
	detections = object_detection_model([img_tensor])[0]
	threshold = 0.8
	boxes = []
	object_list = []
	for box, score, label in zip(detections["boxes"], detections["scores"], detections["labels"]):
	if score > threshold:
	boxes.append(tuple(box.int().cpu().numpy()))
	label_idx = int(label)
	label_name = object_categories[label_idx] if label_idx < len(object_categories) else "Unknown"
	object_list.append(f"{label_name} ({score:.2f})")
	text = f"Detected {len(boxes)} object(s)" if boxes else "No objects detected"
	object_list_text = " \| ".join(object_list) if object_list else "None"
	return boxes, text, object_list_text

	def compute_faces_overlay(image):
	frame_bgr = cv2.cvtColor(np.array(image), cv2.COLOR_RGB2BGR)
	h, w, _ = frame_bgr.shape
	frame_bgr_small = cv2.resize(frame_bgr, DESIRED_SIZE)
	small_h, small_w, _ = frame_bgr_small.shape
	frame_rgb_small = cv2.cvtColor(frame_bgr_small, cv2.COLOR_BGR2RGB)
	face_results = face_detection.process(frame_rgb_small)
	boxes = []
	if face_results.detections:
	for detection in face_results.detections:
	bbox = detection.location_data.relative_bounding_box
	x = int(bbox.xmin * small_w)
	y = int(bbox.ymin * small_h)
	box_w = int(bbox.width * small_w)
	box_h = int(bbox.height * small_h)
	boxes.append((x, y, x + box_w, y + box_h))
	text = f"Detected {len(boxes)} face(s)"
	else:
	text = "No faces detected"
	return boxes, text

	# -----------------------------
	# New Facemesh Functions (for Facial Recognition)
	# -----------------------------
	def compute_facemesh_overlay(image):
	"""
	Uses MediaPipe Face Mesh to detect and draw facial landmarks.
	"""
	frame_bgr = cv2.cvtColor(np.array(image), cv2.COLOR_RGB2BGR)
	h, w, _ = frame_bgr.shape
	# Initialize Face Mesh in static mode
	face_mesh = mp.solutions.face_mesh.FaceMesh(
	static_image_mode=True, max_num_faces=1, refine_landmarks=True, min_detection_confidence=0.5
	)
	results = face_mesh.process(cv2.cvtColor(frame_bgr, cv2.COLOR_BGR2RGB))
	if results.multi_face_landmarks:
	for face_landmarks in results.multi_face_landmarks:
	for landmark in face_landmarks.landmark:
	x = int(landmark.x * w)
	y = int(landmark.y * h)
	cv2.circle(frame_bgr, (x, y), 1, (0, 255, 0), -1)
	text = "Facemesh detected"
	else:
	text = "No facemesh detected"
	face_mesh.close()
	return frame_bgr, text

	def analyze_facemesh(image):
	annotated_image, text = compute_facemesh_overlay(image)
	return annotated_image, f"<div style='color: lime !important;'>Facemesh Analysis: {text}</div>"

	# -----------------------------
	# Main Analysis Functions for Single Image
	# -----------------------------
	def analyze_posture_current(image):
	global posture_cache
	posture_cache["counter"] += 1
	current_frame = np.array(image)
	if posture_cache["counter"] % SKIP_RATE == 0 or posture_cache["landmarks"] is None:
	landmarks, text = compute_posture_overlay(image)
	posture_cache["landmarks"] = landmarks
	posture_cache["text"] = text
	output = current_frame.copy()
	if posture_cache["landmarks"]:
	output = draw_posture_overlay(output, posture_cache["landmarks"])
	return output, f"<div style='color: lime !important;'>Posture Analysis: {posture_cache['text']}</div>"

	def analyze_emotion_current(image):
	global emotion_cache
	emotion_cache["counter"] += 1
	current_frame = np.array(image)
	if emotion_cache["counter"] % SKIP_RATE == 0 or emotion_cache["text"] is None:
	text = compute_emotion_overlay(image)
	emotion_cache["text"] = text
	return current_frame, f"<div style='color: lime !important;'>Emotion Analysis: {emotion_cache['text']}</div>"

	def analyze_objects_current(image):
	global objects_cache
	objects_cache["counter"] += 1
	current_frame = np.array(image)
	if objects_cache["counter"] % SKIP_RATE == 0 or objects_cache["boxes"] is None:
	boxes, text, object_list_text = compute_objects_overlay(image)
	objects_cache["boxes"] = boxes
	objects_cache["text"] = text
	objects_cache["object_list_text"] = object_list_text
	output = current_frame.copy()
	if objects_cache["boxes"]:
	output = draw_boxes_overlay(output, objects_cache["boxes"], (255, 255, 0))
	combined_text = f"Object Detection: {objects_cache['text']}<br>Details: {objects_cache['object_list_text']}"
	return output, f"<div style='color: lime !important;'>{combined_text}</div>"

	def analyze_faces_current(image):
	global faces_cache
	faces_cache["counter"] += 1
	current_frame = np.array(image)
	if faces_cache["counter"] % SKIP_RATE == 0 or faces_cache["boxes"] is None:
	boxes, text = compute_faces_overlay(image)
	faces_cache["boxes"] = boxes
	faces_cache["text"] = text
	output = current_frame.copy()
	if faces_cache["boxes"]:
	output = draw_boxes_overlay(output, faces_cache["boxes"], (0, 0, 255))
	return output, f"<div style='color: lime !important;'>Face Detection: {faces_cache['text']}</div>"

	def analyze_all(image):
	current_frame = np.array(image).copy()
	landmarks, posture_text = compute_posture_overlay(image)
	if landmarks:
	current_frame = draw_posture_overlay(current_frame, landmarks)
	emotion_text = compute_emotion_overlay(image)
	boxes_obj, objects_text, object_list_text = compute_objects_overlay(image)
	if boxes_obj:
	current_frame = draw_boxes_overlay(current_frame, boxes_obj, (255, 255, 0))
	boxes_face, faces_text = compute_faces_overlay(image)
	if boxes_face:
	current_frame = draw_boxes_overlay(current_frame, boxes_face, (0, 0, 255))
	combined_text = (
	f"<b>Posture Analysis:</b> {posture_text}<br>"
	f"<b>Emotion Analysis:</b> {emotion_text}<br>"
	f"<b>Object Detection:</b> {objects_text}<br>"
	f"<b>Detected Objects:</b> {object_list_text}<br>"
	f"<b>Face Detection:</b> {faces_text}"
	)
	if object_list_text and object_list_text != "None":
	description_text = f"Image Description: The scene features {object_list_text}."
	else:
	description_text = "Image Description: No prominent objects detected."
	combined_text += f"<br><br><div style='border:1px solid lime; padding:10px; box-shadow: 0 0 10px lime;'><b>{description_text}</b></div>"
	combined_text_html = f"<div style='color: lime !important;'>{combined_text}</div>"
	return current_frame, combined_text_html

	# -----------------------------
	# Custom CSS (High-Tech Neon Theme)
	# -----------------------------
	custom_css = """
	@import url('https://fonts.googleapis.com/css2?family=Orbitron:wght@400;700&display=swap');
	body {
	background-color: #0e0e0e;
	font-family: 'Orbitron', sans-serif;
	color: #32CD32;
	}
	.gradio-container {
	background: linear-gradient(135deg, #1a1a1a, #333333);
	border: 2px solid #32CD32;
	box-shadow: 0 0 15px #32CD32;
	border-radius: 10px;
	padding: 20px;
	max-width: 1200px;
	margin: auto;
	}
	.gradio-title, .gradio-description, .tab-item, .tab-item * {
	color: #32CD32 !important;
	text-shadow: 0 0 10px #32CD32;
	}
	input, button, .output {
	border: 1px solid #32CD32;
	box-shadow: 0 0 8px #32CD32;
	color: #32CD32;
	}
	"""

	# -----------------------------
	# Create Individual Interfaces for Image Processing
	# -----------------------------
	posture_interface = gr.Interface(
	fn=analyze_posture_current,
	inputs=gr.Image(label="Upload an Image for Posture Analysis"),
	outputs=[gr.Image(type="numpy", label="Annotated Output"), gr.HTML(label="Posture Analysis")],
	title="Posture",
	description="Detects your posture using MediaPipe with connector lines.",
	live=False
	)

	emotion_interface = gr.Interface(
	fn=analyze_emotion_current,
	inputs=gr.Image(label="Upload an Image for Emotion Analysis"),
	outputs=[gr.Image(type="numpy", label="Annotated Output"), gr.HTML(label="Emotion Analysis")],
	title="Emotion",
	description="Detects facial emotions using FER.",
	live=False
	)

	objects_interface = gr.Interface(
	fn=analyze_objects_current,
	inputs=gr.Image(label="Upload an Image for Object Detection"),
	outputs=[gr.Image(type="numpy", label="Annotated Output"), gr.HTML(label="Object Detection")],
	title="Objects",
	description="Detects objects using a pretrained Faster R-CNN.",
	live=False
	)

	faces_interface = gr.Interface(
	fn=analyze_faces_current,
	inputs=gr.Image(label="Upload an Image for Face Detection"),
	outputs=[gr.Image(type="numpy", label="Annotated Output"), gr.HTML(label="Face Detection")],
	title="Faces",
	description="Detects faces using MediaPipe.",
	live=False
	)

	# -----------------------------
	# New Facemesh Interface (Used for facial recognition via facemesh)
	# -----------------------------
	facemesh_interface = gr.Interface(
	fn=analyze_facemesh,
	inputs=gr.Image(label="Upload an Image for Facemesh"),
	outputs=[gr.Image(type="numpy", label="Annotated Output"), gr.HTML(label="Facemesh Analysis")],
	title="Facemesh",
	description="Detects facial landmarks using MediaPipe Face Mesh.",
	live=False
	)

	all_interface = gr.Interface(
	fn=analyze_all,
	inputs=gr.Image(label="Upload an Image for All Inferences"),
	outputs=[gr.Image(type="numpy", label="Annotated Output"), gr.HTML(label="Combined Analysis")],
	title="All Inferences",
	description="Runs posture, emotion, object, and face detection all at once.",
	live=False
	)

	tabbed_interface = gr.TabbedInterface(
	interface_list=[
	posture_interface,
	emotion_interface,
	objects_interface,
	faces_interface,
	facemesh_interface,
	all_interface
	],
	tab_names=[
	"Posture",
	"Emotion",
	"Objects",
	"Faces",
	"Facemesh",
	"All Inferences"
	]
	)

	# -----------------------------
	# Wrap in a Blocks Layout and Launch
	# -----------------------------
	demo = gr.Blocks(css=custom_css)
	with demo:
	gr.Markdown("<h1 class='gradio-title' style='color: #32CD32;'>Multi-Analysis Image App</h1>")
	gr.Markdown("<p class='gradio-description' style='color: #32CD32;'>Upload an image to run high-tech analysis for posture, emotions, objects, faces, and facemesh landmarks.</p>")
	tabbed_interface.render()

	if __name__ == "__main__":
	demo.launch()