app.py

import os
import cv2
import numpy as np
import torch
import torch.nn as nn
import torch.optim as optim
from facenet_pytorch import InceptionResnetV1, MTCNN
import mediapipe as mp
from fer import FER
from sklearn.cluster import KMeans
from sklearn.preprocessing import StandardScaler, MinMaxScaler
from sklearn.metrics import silhouette_score
from scipy.spatial.distance import cdist
import umap
import pandas as pd
import matplotlib.pyplot as plt
from matplotlib.ticker import MaxNLocator
import gradio as gr
import tempfile
import shutil
import subprocess
import fractions

# Suppress TensorFlow warnings
os.environ['TF_CPP_MIN_LOG_LEVEL'] = '2'
import tensorflow as tf
tf.get_logger().setLevel('ERROR')

# Initialize models and other global variables
device = 'cuda' if torch.cuda.is_available() else 'cpu'

mtcnn = MTCNN(keep_all=False, device=device, thresholds=[0.999, 0.999, 0.999], min_face_size=100, selection_method='largest')
model = InceptionResnetV1(pretrained='vggface2').eval().to(device)
mp_face_mesh = mp.solutions.face_mesh
face_mesh = mp_face_mesh.FaceMesh(static_image_mode=False, max_num_faces=1, min_detection_confidence=0.5)
emotion_detector = FER(mtcnn=False)

def frame_to_timecode(frame_num, original_fps, desired_fps):
    total_seconds = frame_num / original_fps
    hours = int(total_seconds // 3600)
    minutes = int((total_seconds % 3600) // 60)
    seconds = int(total_seconds % 60)
    milliseconds = int((total_seconds - int(total_seconds)) * 1000)
    return f"{hours:02d}:{minutes:02d}:{seconds:02d}.{milliseconds:03d}"

def get_face_embedding_and_emotion(face_img):
    face_tensor = torch.tensor(face_img).permute(2, 0, 1).unsqueeze(0).float() / 255
    face_tensor = (face_tensor - 0.5) / 0.5
    face_tensor = face_tensor.to(device)
    with torch.no_grad():
        embedding = model(face_tensor)

    emotions = emotion_detector.detect_emotions(face_img)
    if emotions:
        emotion_dict = emotions[0]['emotions']
    else:
        emotion_dict = {e: 0 for e in ['angry', 'disgust', 'fear', 'happy', 'sad', 'surprise', 'neutral']}

    return embedding.cpu().numpy().flatten(), emotion_dict

def alignFace(img):
    img_raw = img.copy()
    results = face_mesh.process(cv2.cvtColor(img, cv2.COLOR_BGR2RGB))
    if not results.multi_face_landmarks:
        return None
    landmarks = results.multi_face_landmarks[0].landmark
    left_eye = np.array([[landmarks[33].x, landmarks[33].y], [landmarks[160].x, landmarks[160].y],
                         [landmarks[158].x, landmarks[158].y], [landmarks[144].x, landmarks[144].y],
                         [landmarks[153].x, landmarks[153].y], [landmarks[145].x, landmarks[145].y]])
    right_eye = np.array([[landmarks[362].x, landmarks[362].y], [landmarks[385].x, landmarks[385].y],
                          [landmarks[387].x, landmarks[387].y], [landmarks[263].x, landmarks[263].y],
                          [landmarks[373].x, landmarks[373].y], [landmarks[380].x, landmarks[380].y]])
    left_eye_center = left_eye.mean(axis=0).astype(np.int32)
    right_eye_center = right_eye.mean(axis=0).astype(np.int32)
    dY = right_eye_center[1] - left_eye_center[1]
    dX = right_eye_center[0] - left_eye_center[0]
    angle = np.degrees(np.arctan2(dY, dX))
    desired_angle = 0
    angle_diff = desired_angle - angle
    height, width = img_raw.shape[:2]
    center = (width // 2, height // 2)
    rotation_matrix = cv2.getRotationMatrix2D(center, angle_diff, 1)
    new_img = cv2.warpAffine(img_raw, rotation_matrix, (width, height))
    return new_img

def extract_frames(video_path, output_folder, fps):
    os.makedirs(output_folder, exist_ok=True)
    command = [
        'ffmpeg',
        '-i', video_path,
        '-vf', f'fps={fps}',
        f'{output_folder}/frame_%04d.jpg'
    ]
    try:
        result = subprocess.run(command, check=True, capture_output=True, text=True)
        print(f"FFmpeg stdout: {result.stdout}")
        print(f"FFmpeg stderr: {result.stderr}")
    except subprocess.CalledProcessError as e:
        print(f"Error extracting frames: {e}")
        print(f"FFmpeg stdout: {e.stdout}")
        print(f"FFmpeg stderr: {e.stderr}")
        raise

def get_video_info(video_path):
    ffprobe_command = [
        'ffprobe',
        '-v', 'error',
        '-select_streams', 'v:0',
        '-count_packets',
        '-show_entries', 'stream=nb_read_packets,r_frame_rate',
        '-of', 'csv=p=0',
        video_path
    ]
    ffprobe_output = subprocess.check_output(ffprobe_command, universal_newlines=True).strip().split(',')
    frame_rate, frame_count = ffprobe_output
    
    frac = fractions.Fraction(frame_rate)
    original_fps = float(frac.numerator) / float(frac.denominator)
    frame_count = int(frame_count)
    
    return frame_count, original_fps

def process_frames(frames_folder, aligned_faces_folder, frame_count, progress, batch_size):
    embeddings_by_frame = {}
    emotions_by_frame = {}
    frame_files = sorted([f for f in os.listdir(frames_folder) if f.endswith('.jpg')])
    
    for i in range(0, len(frame_files), batch_size):
        batch_files = frame_files[i:i+batch_size]
        batch_frames = []
        batch_nums = []
        
        for frame_file in batch_files:
            frame_num = int(frame_file.split('_')[1].split('.')[0])
            frame_path = os.path.join(frames_folder, frame_file)
            frame = cv2.imread(frame_path)
            if frame is not None:
                batch_frames.append(frame)
                batch_nums.append(frame_num)
        
        if batch_frames:
            # Detect faces in batch
            batch_boxes, batch_probs = mtcnn.detect(batch_frames)
            
            for j, (frame, frame_num, boxes, probs) in enumerate(zip(batch_frames, batch_nums, batch_boxes, batch_probs)):
                if boxes is not None and len(boxes) > 0 and probs[0] >= 0.99:
                    x1, y1, x2, y2 = [int(b) for b in boxes[0]]
                    face = frame[y1:y2, x1:x2]
                    if face.size > 0:
                        aligned_face = alignFace(face)
                        if aligned_face is not None:
                            aligned_face_resized = cv2.resize(aligned_face, (160, 160))
                            output_path = os.path.join(aligned_faces_folder, f"frame_{frame_num}_face.jpg")
                            cv2.imwrite(output_path, aligned_face_resized)
                            embedding, emotion = get_face_embedding_and_emotion(aligned_face_resized)
                            embeddings_by_frame[frame_num] = embedding
                            emotions_by_frame[frame_num] = emotion
        
        progress((i + len(batch_files)) / frame_count, f"Processing frames {i + 1} to {min(i + len(batch_files), frame_count)} of {frame_count}")

    return embeddings_by_frame, emotions_by_frame

def cluster_embeddings(embeddings):
    if len(embeddings) < 2:
        print("Not enough embeddings for clustering. Assigning all to one cluster.")
        return np.zeros(len(embeddings), dtype=int)
    n_clusters = min(3, len(embeddings))  # Use at most 3 clusters
    scaler = StandardScaler()
    embeddings_scaled = scaler.fit_transform(embeddings)
    kmeans = KMeans(n_clusters=n_clusters, random_state=42, n_init=10)
    clusters = kmeans.fit_predict(embeddings_scaled)
    return clusters

def organize_faces_by_person(embeddings_by_frame, clusters, aligned_faces_folder, organized_faces_folder):
    for (frame_num, embedding), cluster in zip(embeddings_by_frame.items(), clusters):
        person_folder = os.path.join(organized_faces_folder, f"person_{cluster}")
        os.makedirs(person_folder, exist_ok=True)
        src = os.path.join(aligned_faces_folder, f"frame_{frame_num}_face.jpg")
        dst = os.path.join(person_folder, f"frame_{frame_num}_face.jpg")
        shutil.copy(src, dst)

def save_person_data_to_csv(embeddings_by_frame, emotions_by_frame, clusters, desired_fps, original_fps, output_folder, num_components):
    emotions = ['angry', 'disgust', 'fear', 'happy', 'sad', 'neutral']
    person_data = {}

    for (frame_num, embedding), (_, emotion_dict), cluster in zip(embeddings_by_frame.items(),
                                                                  emotions_by_frame.items(), clusters):
        if cluster not in person_data:
            person_data[cluster] = []
        person_data[cluster].append((frame_num, embedding, {e: emotion_dict[e] for e in emotions}))

    largest_cluster = max(person_data, key=lambda k: len(person_data[k]))

    data = person_data[largest_cluster]
    data.sort(key=lambda x: x[0])
    frames, embeddings, emotions_data = zip(*data)

    embeddings_array = np.array(embeddings)
    np.save(os.path.join(output_folder, 'face_embeddings.npy'), embeddings_array)

    reducer = umap.UMAP(n_components=num_components, random_state=1)
    embeddings_reduced = reducer.fit_transform(embeddings)

    scaler = MinMaxScaler(feature_range=(0, 1))
    embeddings_reduced_normalized = scaler.fit_transform(embeddings_reduced)

    timecodes = [frame_to_timecode(frame, original_fps, desired_fps) for frame in frames]
    times_in_minutes = [frame / (original_fps * 60) for frame in frames]

    df_data = {
        'Frame': frames,
        'Timecode': timecodes,
        'Time (Minutes)': times_in_minutes,
        'Embedding_Index': range(len(embeddings))
    }

    for i in range(num_components):
        df_data[f'Comp {i + 1}'] = embeddings_reduced_normalized[:, i]

    for emotion in emotions:
        df_data[emotion] = [e[emotion] for e in emotions_data]

    df = pd.DataFrame(df_data)

    return df, largest_cluster

class LSTMAutoencoder(nn.Module):
    def __init__(self, input_size, hidden_size=64, num_layers=2):
        super(LSTMAutoencoder, self).__init__()
        self.input_size = input_size
        self.hidden_size = hidden_size
        self.num_layers = num_layers

        self.lstm = nn.LSTM(input_size, hidden_size, num_layers, batch_first=True)
        self.fc = nn.Linear(hidden_size, input_size)

    def forward(self, x):
        _, (hidden, _) = self.lstm(x)
        out = self.fc(hidden[-1])
        return out

def lstm_anomaly_detection(X, feature_columns, num_anomalies=10, epochs=100, batch_size=64):
    device = 'cuda' if torch.cuda.is_available() else 'cpu'

    X = torch.FloatTensor(X).to(device)

    # Ensure X is 2D
    if X.dim() == 1:
        X = X.unsqueeze(1)  # Add a feature dimension
    elif X.dim() > 2:
        raise ValueError(f"Input X should be 1D or 2D, but got {X.dim()} dimensions")

    train_size = int(0.85 * len(X))
    X_train, X_val = X[:train_size], X[train_size:]

    model = LSTMAutoencoder(input_size=X.shape[1]).to(device)
    criterion = nn.MSELoss()
    optimizer = optim.Adam(model.parameters())

    for epoch in range(epochs):
        model.train()
        optimizer.zero_grad()
        output_train = model(X_train.unsqueeze(0))
        loss_train = criterion(output_train, X_train)
        loss_train.backward()
        optimizer.step()

        model.eval()
        with torch.no_grad():
            output_val = model(X_val.unsqueeze(0))
            loss_val = criterion(output_val, X_val)

    model.eval()
    with torch.no_grad():
        reconstructed = model(X.unsqueeze(0)).squeeze(0).cpu().numpy()

    # Compute anomalies for all features
    mse_all = np.mean(np.power(X.cpu().numpy() - reconstructed, 2), axis=1)
    top_indices_all = mse_all.argsort()[-num_anomalies:][::-1]
    anomalies_all = np.zeros(len(mse_all), dtype=bool)
    anomalies_all[top_indices_all] = True

    # Compute anomalies for components only
    component_columns = [col for col in feature_columns if col.startswith('Comp')]
    component_indices = [feature_columns.index(col) for col in component_columns]
    
    if len(component_indices) > 0:
        if X.dim() == 1:
            mse_comp = mse_all  # If X is 1D, we can't select specific components
        else:
            mse_comp = np.mean(np.power(X.cpu().numpy()[:, component_indices] - reconstructed[:, component_indices], 2), axis=1)
    else:
        mse_comp = mse_all  # If no components, use all features

    top_indices_comp = mse_comp.argsort()[-num_anomalies:][::-1]
    anomalies_comp = np.zeros(len(mse_comp), dtype=bool)
    anomalies_comp[top_indices_comp] = True

    return (anomalies_all, mse_all, top_indices_all, 
                anomalies_comp, mse_comp, top_indices_comp, 
                model)

def plot_anomaly_scores(df, anomaly_scores, top_indices, title):
    fig, ax = plt.subplots(figsize=(16, 8))
    bars = ax.bar(range(len(df)), anomaly_scores, width=0.8, color='skyblue')
    for i in top_indices:
        bars[i].set_color('red')
    ax.set_xlabel('Timecode')
    ax.set_ylabel('Anomaly Score')
    ax.set_title(f'Anomaly Scores Over Time ({title})')
    ax.xaxis.set_major_locator(MaxNLocator(nbins=100))
    ticks = ax.get_xticks()
    ax.set_xticklabels([df['Timecode'].iloc[int(tick)] if tick >= 0 and tick < len(df) else '' for tick in ticks], rotation=90, ha='right')
    plt.tight_layout()
    return fig

def plot_emotion(df, emotion, num_anomalies):
    fig, ax = plt.subplots(figsize=(16, 8))
    values = df[emotion].values
    bars = ax.bar(range(len(df)), values, width=0.8, color='lightgreen')
    top_indices = np.argsort(values)[-num_anomalies:][::-1]
    for i in top_indices:
        bars[i].set_color('red')
    ax.set_xlabel('Timecode')
    ax.set_ylabel(f'{emotion.capitalize()} Score')
    ax.set_title(f'{emotion.capitalize()} Scores Over Time (Top {num_anomalies} in Red)')
    ax.xaxis.set_major_locator(MaxNLocator(nbins=100))
    ticks = ax.get_xticks()
    ax.set_xticklabels([df['Timecode'].iloc[int(tick)] if tick >= 0 and tick < len(df) else '' for tick in ticks], rotation=90, ha='right')
    plt.tight_layout()
    return fig

def plot_components(df):
    fig, ax = plt.subplots(figsize=(16, 8))
    component_columns = [col for col in df.columns if col.startswith('Comp')]
    for col in component_columns:
        ax.plot(df['Time (Minutes)'], df[col], label=col)
    ax.set_xlabel('Time (Minutes)')
    ax.set_ylabel('Component Value')
    ax.set_title('UMAP Components Over Time')
    ax.legend()
    plt.tight_layout()
    return fig

def process_video(video_path, num_anomalies, num_components, desired_fps, batch_size, progress=gr.Progress()):
    with tempfile.TemporaryDirectory() as temp_dir:
        aligned_faces_folder = os.path.join(temp_dir, 'aligned_faces')
        organized_faces_folder = os.path.join(temp_dir, 'organized_faces')
        os.makedirs(aligned_faces_folder, exist_ok=True)
        os.makedirs(organized_faces_folder, exist_ok=True)

        progress(0.1, "Extracting frames")
        frames_folder = os.path.join(temp_dir, 'extracted_frames')
        extract_frames(video_path, frames_folder, desired_fps)

        progress(0.2, "Getting video info")
        frame_count, original_fps = get_video_info(video_path)

        progress(0.3, "Processing frames")
        embeddings_by_frame, emotions_by_frame = process_frames(frames_folder, aligned_faces_folder, frame_count, progress, batch_size)

        if not embeddings_by_frame:
            return "No faces were extracted from the video.", None, None, None, None, None, None

        progress(0.6, "Clustering embeddings")
        embeddings = list(embeddings_by_frame.values())
        clusters = cluster_embeddings(embeddings)

        progress(0.7, "Organizing faces")
        organize_faces_by_person(embeddings_by_frame, clusters, aligned_faces_folder, organized_faces_folder)

        progress(0.8, "Saving person data")
        df, largest_cluster = save_person_data_to_csv(embeddings_by_frame, emotions_by_frame, clusters, desired_fps, original_fps, temp_dir, num_components)

        progress(0.9, "Performing anomaly detection")
        feature_columns = [col for col in df.columns if col not in ['Frame', 'Timecode', 'Time (Minutes)', 'Embedding_Index']]
        X = df[feature_columns].values
        print(f"Shape of input data: {X.shape}")  # Debug print
        try:
            anomalies_all, anomaly_scores_all, top_indices_all, anomalies_comp, anomaly_scores_comp, top_indices_comp, _ = lstm_anomaly_detection(X, feature_columns, num_anomalies=num_anomalies, batch_size=batch_size)
        except Exception as e:
            return f"Error in anomaly detection: {str(e)}", None, None, None, None, None, None
        
        progress(0.95, "Generating plots")
        try:
            anomaly_plot_all = plot_anomaly_scores(df, anomaly_scores_all, top_indices_all, "All Features")
            anomaly_plot_comp = plot_anomaly_scores(df, anomaly_scores_comp, top_indices_comp, "Components Only")
            components_plot = plot_components(df)
            emotion_plots = [plot_emotion(df, emotion, num_anomalies) for emotion in ['fear', 'sad', 'angry']]
        except Exception as e:
            return f"Error generating plots: {str(e)}", None, None, None, None, None, None

        progress(1.0, "Preparing results")
        results = f"Top {num_anomalies} anomalies (All Features):\n"
        results += "\n".join([f"{score:.4f} at {timecode}" for score, timecode in 
                              zip(anomaly_scores_all[top_indices_all], df['Timecode'].iloc[top_indices_all].values)])
        results += f"\n\nTop {num_anomalies} anomalies (Components Only):\n"
        results += "\n".join([f"{score:.4f} at {timecode}" for score, timecode in 
                              zip(anomaly_scores_comp[top_indices_comp], df['Timecode'].iloc[top_indices_comp].values)])

        for emotion in ['fear', 'sad', 'angry']:
            top_indices = np.argsort(df[emotion].values)[-num_anomalies:][::-1]
            results += f"\n\nTop {num_anomalies} {emotion.capitalize()} Scores:\n"
            results += "\n".join([f"{df[emotion].iloc[i]:.4f} at {df['Timecode'].iloc[i]}" for i in top_indices])

        return results, anomaly_plot_all, anomaly_plot_comp, components_plot, *emotion_plots

# Gradio interface
iface = gr.Interface(
    fn=process_video,
    inputs=[
        gr.Video(),
        gr.Slider(minimum=1, maximum=20, step=1, value=10, label="Number of Anomalies"),
        gr.Slider(minimum=2, maximum=5, step=1, value=3, label="Number of Components"),
        gr.Slider(minimum=1, maximum=30, step=1, value=20, label="Desired FPS"),
        gr.Slider(minimum=1, maximum=64, step=1, value=16, label="Batch Size")
    ],
    outputs=[
        gr.Textbox(label="Anomaly Detection Results"),
        gr.Plot(label="Anomaly Scores (All Features)"),
        gr.Plot(label="Anomaly Scores (Components Only)"),
        gr.Plot(label="UMAP Components"),
        gr.Plot(label="Fear Scores"),
        gr.Plot(label="Sad Scores"),
        gr.Plot(label="Angry Scores")
    ],
    title="Facial Expressions Anomaly Detection",
    description="""
    This application detects anomalies in facial expressions and emotions from a video input. 
    It focuses on the most frequently appearing person in the video for analysis.
    
    Adjust the parameters as needed:
    - Number of Anomalies: How many top anomalies or high intensities to highlight
    - Number of Components: Complexity of the facial expression model
    - Desired FPS: Frames per second to analyze (lower for faster processing)
    - Batch Size: Affects processing speed and memory usage
    """
)

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