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	# Copyright (c) Meta Platforms, Inc. and affiliates.
	# All rights reserved.

	# This source code is licensed under the license found in the
	# LICENSE file in the root directory of this source tree.

	import copy
	import os
	import time
	from datetime import datetime
	import tempfile

	import cv2
	import matplotlib.pyplot as plt
	import numpy as np
	import gradio as gr
	import torch

	from moviepy.editor import ImageSequenceClip
	from PIL import Image
	from sam2.build_sam import build_sam2_video_predictor

	# Remove CUDA environment variables
	if 'TORCH_CUDNN_SDPA_ENABLED' in os.environ:
	del os.environ["TORCH_CUDNN_SDPA_ENABLED"]

	# Description
	title = "<center><strong><font size='8'>EdgeTAM CPU<font></strong> <a href='https://github.com/facebookresearch/EdgeTAM'><font size='6'>[GitHub]</font></a> </center>"

	description_p = """# Instructions
	<ol>
	<li> Upload one video or click one example video</li>
	<li> Click 'include' point type, select the object to segment and track</li>
	<li> Click 'exclude' point type (optional), select the area you want to avoid segmenting and tracking</li>
	<li> Click the 'Track' button to obtain the masked video </li>
	</ol>
	"""

	# examples - keeping fewer examples to reduce memory footprint
	examples = [
	["examples/01_dog.mp4"],
	["examples/02_cups.mp4"],
	["examples/03_blocks.mp4"],
	["examples/04_coffee.mp4"],
	["examples/05_default_juggle.mp4"],
	]

	OBJ_ID = 0

	# Initialize model on CPU - add error handling for file paths
	sam2_checkpoint = "checkpoints/edgetam.pt"
	model_cfg = "edgetam.yaml"

	# Check if model files exist
	def check_file_exists(filepath):
	exists = os.path.exists(filepath)
	if not exists:
	print(f"WARNING: File not found: {filepath}")
	return exists

	# Verify files exist
	model_files_exist = check_file_exists(sam2_checkpoint) and check_file_exists(model_cfg)
	predictor = None
	try:
	# Load model with careful error handling
	predictor = build_sam2_video_predictor(model_cfg, sam2_checkpoint, device="cpu")
	print("predictor loaded on CPU")
	except Exception as e:
	print(f"Error loading model: {e}")
	import traceback
	traceback.print_exc()

	# Function to get video frame rate
	def get_video_fps(video_path):
	cap = cv2.VideoCapture(video_path)
	if not cap.isOpened():
	print("Error: Could not open video.")
	return 30.0 # Default fallback value
	fps = cap.get(cv2.CAP_PROP_FPS)
	cap.release()
	return fps

	def reset(session_state):
	"""Reset all session state variables and UI elements."""
	session_state["input_points"] = []
	session_state["input_labels"] = []
	if session_state["inference_state"] is not None:
	predictor.reset_state(session_state["inference_state"])
	session_state["first_frame"] = None
	session_state["all_frames"] = None
	session_state["inference_state"] = None
	session_state["progress"] = 0
	return (
	None,
	gr.update(open=True),
	None,
	None,
	gr.update(value=None, visible=False),
	gr.update(value=0, visible=False),
	session_state,
	)

	def clear_points(session_state):
	"""Clear tracking points while keeping the video frames."""
	session_state["input_points"] = []
	session_state["input_labels"] = []
	if session_state["inference_state"] is not None and session_state["inference_state"].get("tracking_has_started", False):
	predictor.reset_state(session_state["inference_state"])
	return (
	session_state["first_frame"],
	None,
	gr.update(value=None, visible=False),
	gr.update(value=0, visible=False),
	session_state,
	)

	def preprocess_video_in(video_path, session_state):
	"""Process input video to extract frames for tracking."""
	if video_path is None or not os.path.exists(video_path):
	return (
	gr.update(open=True), # video_in_drawer
	None, # points_map
	None, # output_image
	gr.update(value=None, visible=False), # output_video
	gr.update(value=0, visible=False), # progress_bar
	session_state,
	)

	# Read the first frame
	cap = cv2.VideoCapture(video_path)
	if not cap.isOpened():
	print(f"Error: Could not open video at {video_path}.")
	return (
	gr.update(open=True), # video_in_drawer
	None, # points_map
	None, # output_image
	gr.update(value=None, visible=False), # output_video
	gr.update(value=0, visible=False), # progress_bar
	session_state,
	)

	# For CPU optimization - determine video properties
	frame_width = int(cap.get(cv2.CAP_PROP_FRAME_WIDTH))
	frame_height = int(cap.get(cv2.CAP_PROP_FRAME_HEIGHT))
	total_frames = int(cap.get(cv2.CAP_PROP_FRAME_COUNT))
	fps = cap.get(cv2.CAP_PROP_FPS)

	print(f"Video info: {frame_width}x{frame_height}, {total_frames} frames, {fps} FPS")

	# Determine if we need to resize for CPU performance
	target_width = 640 # Target width for processing on CPU
	scale_factor = 1.0

	if frame_width > target_width:
	scale_factor = target_width / frame_width
	new_width = int(frame_width * scale_factor)
	new_height = int(frame_height * scale_factor)
	print(f"Resizing video for CPU processing: {frame_width}x{frame_height} -> {new_width}x{new_height}")

	# Read frames - for CPU we'll be more selective about which frames to keep
	frame_number = 0
	first_frame = None
	all_frames = []

	# For CPU optimization, skip frames if video is too long
	frame_stride = 1
	if total_frames > 300: # If more than 300 frames
	frame_stride = max(1, int(total_frames / 300)) # Process at most ~300 frames
	print(f"Video has {total_frames} frames, using stride of {frame_stride} to reduce processing load")

	while True:
	ret, frame = cap.read()
	if not ret:
	break

	if frame_number % frame_stride == 0: # Process every frame_stride frames
	try:
	# Resize the frame if needed
	if scale_factor != 1.0:
	frame = cv2.resize(
	frame,
	(int(frame_width * scale_factor), int(frame_height * scale_factor)),
	interpolation=cv2.INTER_AREA
	)

	frame = cv2.cvtColor(frame, cv2.COLOR_BGR2RGB)
	frame = np.array(frame)

	# Store the first frame
	if first_frame is None:
	first_frame = frame
	all_frames.append(frame)
	except Exception as e:
	print(f"Error processing frame {frame_number}: {e}")

	frame_number += 1

	cap.release()

	# Ensure we have at least one frame
	if first_frame is None or len(all_frames) == 0:
	print("Error: No frames could be extracted from the video.")
	return (
	gr.update(open=True), # video_in_drawer
	None, # points_map
	None, # output_image
	gr.update(value=None, visible=False), # output_video
	gr.update(value=0, visible=False), # progress_bar
	session_state,
	)

	print(f"Successfully extracted {len(all_frames)} frames from video")

	session_state["first_frame"] = copy.deepcopy(first_frame)
	session_state["all_frames"] = all_frames
	session_state["frame_stride"] = frame_stride
	session_state["scale_factor"] = scale_factor
	session_state["original_dimensions"] = (frame_width, frame_height)
	session_state["progress"] = 0

	try:
	session_state["inference_state"] = predictor.init_state(video_path=video_path)
	session_state["input_points"] = []
	session_state["input_labels"] = []
	except Exception as e:
	print(f"Error initializing inference state: {e}")
	import traceback
	traceback.print_exc()
	session_state["inference_state"] = None

	return [
	gr.update(open=False), # video_in_drawer
	first_frame, # points_map
	None, # output_image
	gr.update(value=None, visible=False), # output_video
	gr.update(value=0, visible=False), # progress_bar
	session_state,
	]

	def segment_with_points(
	point_type,
	session_state,
	evt: gr.SelectData,
	):
	"""Add and process tracking points on the first frame."""
	if session_state["first_frame"] is None:
	print("Error: No frame available for segmentation")
	return None, None, session_state

	session_state["input_points"].append(evt.index)
	print(f"TRACKING INPUT POINT: {session_state['input_points']}")

	if point_type == "include":
	session_state["input_labels"].append(1)
	elif point_type == "exclude":
	session_state["input_labels"].append(0)
	print(f"TRACKING INPUT LABEL: {session_state['input_labels']}")

	# Open the image and get its dimensions
	first_frame = session_state["first_frame"]
	h, w = first_frame.shape[:2]
	transparent_background = Image.fromarray(first_frame).convert("RGBA")

	# Define the circle radius as a fraction of the smaller dimension
	fraction = 0.01 # You can adjust this value as needed
	radius = int(fraction * min(w, h))

	# Create a transparent layer to draw on
	transparent_layer = np.zeros((h, w, 4), dtype=np.uint8)

	for index, track in enumerate(session_state["input_points"]):
	if session_state["input_labels"][index] == 1:
	cv2.circle(transparent_layer, track, radius, (0, 255, 0, 255), -1) # Green for include
	else:
	cv2.circle(transparent_layer, track, radius, (255, 0, 0, 255), -1) # Red for exclude

	# Convert the transparent layer back to an image
	transparent_layer = Image.fromarray(transparent_layer, "RGBA")
	selected_point_map = Image.alpha_composite(
	transparent_background, transparent_layer
	)

	# Let's add a positive click at (x, y) = (210, 350) to get started
	points = np.array(session_state["input_points"], dtype=np.float32)
	# for labels, `1` means positive click and `0` means negative click
	labels = np.array(session_state["input_labels"], np.int32)

	try:
	if predictor is None:
	raise ValueError("Model predictor is not initialized")

	if session_state["inference_state"] is None:
	raise ValueError("Inference state is not initialized")

	# For CPU optimization, we'll process with smaller batch size
	_, _, out_mask_logits = predictor.add_new_points(
	inference_state=session_state["inference_state"],
	frame_idx=0,
	obj_id=OBJ_ID,
	points=points,
	labels=labels,
	)

	# Create the mask
	mask_array = (out_mask_logits[0] > 0.0).cpu().numpy()

	# Ensure the mask has the same size as the frame
	if mask_array.shape[:2] != (h, w):
	mask_array = cv2.resize(
	mask_array.astype(np.uint8),
	(w, h),
	interpolation=cv2.INTER_NEAREST
	).astype(bool)

	mask_image = show_mask(mask_array)

	# Make sure mask_image has the same size as the background
	if mask_image.size != transparent_background.size:
	mask_image = mask_image.resize(transparent_background.size, Image.NEAREST)

	first_frame_output = Image.alpha_composite(transparent_background, mask_image)
	except Exception as e:
	print(f"Error in segmentation: {e}")
	import traceback
	traceback.print_exc()
	# Return just the points as fallback
	first_frame_output = selected_point_map

	return selected_point_map, first_frame_output, session_state

	def show_mask(mask, obj_id=None, random_color=False, convert_to_image=True):
	"""Convert binary mask to RGBA image for visualization."""
	if random_color:
	color = np.concatenate([np.random.random(3), np.array([0.6])], axis=0)
	else:
	cmap = plt.get_cmap("tab10")
	cmap_idx = 0 if obj_id is None else obj_id
	color = np.array([*cmap(cmap_idx)[:3], 0.6])

	# Handle different mask shapes properly
	if len(mask.shape) == 2:
	h, w = mask.shape
	else:
	h, w = mask.shape[-2:]

	# Ensure correct reshaping based on mask dimensions
	mask_reshaped = mask.reshape(h, w, 1) * color.reshape(1, 1, -1)
	mask_rgba = (mask_reshaped * 255).astype(np.uint8)

	if convert_to_image:
	try:
	# Ensure the mask has correct RGBA shape (h, w, 4)
	if mask_rgba.shape[2] != 4:
	# If not RGBA, create a proper RGBA array
	proper_mask = np.zeros((h, w, 4), dtype=np.uint8)
	# Copy available channels
	proper_mask[:, :, :min(mask_rgba.shape[2], 4)] = mask_rgba[:, :, :min(mask_rgba.shape[2], 4)]
	mask_rgba = proper_mask

	# Create the PIL image
	return Image.fromarray(mask_rgba, "RGBA")
	except Exception as e:
	print(f"Error converting mask to image: {e}")
	# Fallback: create a blank transparent image of correct size
	blank = np.zeros((h, w, 4), dtype=np.uint8)
	return Image.fromarray(blank, "RGBA")

	return mask_rgba

	def update_progress(progress_percent, progress_bar):
	"""Update progress bar during processing."""
	return gr.update(value=progress_percent, visible=True)

	def propagate_to_all(
	video_in,
	session_state,
	progress=gr.Progress(),
	):
	"""Process video frames and generate masked video output with progress tracking."""
	if (
	len(session_state["input_points"]) == 0
	or video_in is None
	or session_state["inference_state"] is None
	or predictor is None
	):
	print("Missing required data for tracking")
	return (
	gr.update(value=None, visible=False),
	gr.update(value=0, visible=False),
	session_state,
	)

	# For CPU optimization: process in smaller batches
	chunk_size = 3 # Process 3 frames at a time to avoid memory issues on CPU

	try:
	# run propagation throughout the video and collect the results in a dict
	video_segments = {} # video_segments contains the per-frame segmentation results
	print("Starting propagate_in_video on CPU")

	progress.tqdm.reset()

	# Get the count for progress reporting
	all_frames_count = 0
	for _ in predictor.propagate_in_video(session_state["inference_state"], count_only=True):
	all_frames_count += 1

	print(f"Total frames to process: {all_frames_count}")
	progress.tqdm.total = all_frames_count

	# Now do the actual processing with progress updates
	for out_frame_idx, out_obj_ids, out_mask_logits in predictor.propagate_in_video(
	session_state["inference_state"]
	):
	try:
	# Store the masks for each object ID
	video_segments[out_frame_idx] = {
	out_obj_id: (out_mask_logits[i] > 0.0).cpu().numpy()
	for i, out_obj_id in enumerate(out_obj_ids)
	}

	# Update progress
	progress.tqdm.update(1)
	progress_percent = min(100, int((out_frame_idx + 1) / all_frames_count * 100))
	session_state["progress"] = progress_percent

	if out_frame_idx % 10 == 0:
	print(f"Processed frame {out_frame_idx}/{all_frames_count} ({progress_percent}%)")

	# Release memory periodically
	if out_frame_idx % chunk_size == 0:
	# Explicitly clear any tensors
	del out_mask_logits
	import gc
	gc.collect()
	except Exception as e:
	print(f"Error processing frame {out_frame_idx}: {e}")
	import traceback
	traceback.print_exc()
	continue

	# For CPU optimization: increase stride to reduce processing
	# Create a more aggressive stride to limit to fewer frames in output
	total_frames = len(video_segments)
	print(f"Total frames processed: {total_frames}")

	# Update progress to show rendering phase
	progress.tqdm.reset()
	progress.tqdm.total = 2 # Two phases: rendering and video creation
	progress.tqdm.update(1)
	session_state["progress"] = 50

	# Limit to max 50 frames for CPU processing
	max_output_frames = 50
	vis_frame_stride = max(1, total_frames // max_output_frames)
	print(f"Using stride of {vis_frame_stride} for output video generation")

	# Get dimensions of the frames
	if len(session_state["all_frames"]) == 0:
	raise ValueError("No frames available in session state")

	first_frame = session_state["all_frames"][0]
	h, w = first_frame.shape[:2]

	# Create output frames
	output_frames = []
	progress.tqdm.reset()
	progress.tqdm.total = (total_frames // vis_frame_stride) + 1

	for out_frame_idx in range(0, total_frames, vis_frame_stride):
	if out_frame_idx not in video_segments or OBJ_ID not in video_segments[out_frame_idx]:
	progress.tqdm.update(1)
	continue

	try:
	# Get corresponding frame from all_frames
	if out_frame_idx >= len(session_state["all_frames"]):
	print(f"Warning: Frame index {out_frame_idx} exceeds available frames {len(session_state['all_frames'])}")
	frame_idx = min(out_frame_idx, len(session_state["all_frames"])-1)
	else:
	frame_idx = out_frame_idx

	frame = session_state["all_frames"][frame_idx]
	transparent_background = Image.fromarray(frame).convert("RGBA")

	# Get the mask and ensure it's the right size
	out_mask = video_segments[out_frame_idx][OBJ_ID]

	# Ensure the mask is not empty and has the right dimensions
	if out_mask.size == 0:
	print(f"Warning: Empty mask for frame {out_frame_idx}")
	# Create an empty mask of the right size
	out_mask = np.zeros((h, w), dtype=bool)

	# Resize mask if dimensions don't match
	mask_h, mask_w = out_mask.shape[:2]
	if mask_h != h or mask_w != w:
	print(f"Resizing mask from {mask_h}x{mask_w} to {h}x{w}")
	out_mask = cv2.resize(
	out_mask.astype(np.uint8),
	(w, h),
	interpolation=cv2.INTER_NEAREST
	).astype(bool)

	mask_image = show_mask(out_mask)

	# Make sure mask has same dimensions as background
	if mask_image.size != transparent_background.size:
	mask_image = mask_image.resize(transparent_background.size, Image.NEAREST)

	output_frame = Image.alpha_composite(transparent_background, mask_image)
	output_frame = np.array(output_frame)
	output_frames.append(output_frame)

	# Update progress
	progress.tqdm.update(1)
	progress_percent = 50 + min(50, int((len(output_frames) / (total_frames // vis_frame_stride)) * 50))
	session_state["progress"] = progress_percent

	# Clear memory periodically
	if len(output_frames) % 10 == 0:
	import gc
	gc.collect()

	except Exception as e:
	print(f"Error creating output frame {out_frame_idx}: {e}")
	import traceback
	traceback.print_exc()
	progress.tqdm.update(1)
	continue

	# Create a video clip from the image sequence
	original_fps = get_video_fps(video_in)
	fps = original_fps

	# For CPU optimization - lower FPS if original is high
	if fps > 15:
	fps = 15 # Lower fps for CPU processing

	print(f"Creating video with {len(output_frames)} frames at {fps} FPS")

	# Update progress to show video creation phase
	session_state["progress"] = 90

	# Check if we have any frames to work with
	if len(output_frames) == 0:
	raise ValueError("No output frames were generated")

	# Ensure all frames have the same shape
	first_shape = output_frames[0].shape
	valid_frames = []
	for i, frame in enumerate(output_frames):
	if frame.shape == first_shape:
	valid_frames.append(frame)
	else:
	print(f"Skipping frame {i} with inconsistent shape: {frame.shape} vs {first_shape}")

	if len(valid_frames) == 0:
	raise ValueError("No valid frames with consistent shape")

	clip = ImageSequenceClip(valid_frames, fps=fps)

	# Write the result to a file - use lower quality for CPU
	unique_id = datetime.now().strftime("%Y%m%d%H%M%S")
	final_vid_output_path = f"output_video_{unique_id}.mp4"
	final_vid_output_path = os.path.join(tempfile.gettempdir(), final_vid_output_path)

	# Lower bitrate for CPU processing
	clip.write_videofile(
	final_vid_output_path,
	codec="libx264",
	bitrate="800k",
	threads=2, # Use fewer threads for CPU
	logger=None # Disable logger to reduce console output
	)

	# Complete progress
	session_state["progress"] = 100

	# Free memory
	del video_segments
	del output_frames
	import gc
	gc.collect()

	return (
	gr.update(value=final_vid_output_path, visible=True),
	gr.update(value=100, visible=False),
	session_state,
	)

	except Exception as e:
	print(f"Error in propagate_to_all: {e}")
	import traceback
	traceback.print_exc()
	return (
	gr.update(value=None, visible=False),
	gr.update(value=0, visible=False),
	session_state,
	)

	def update_ui():
	"""Show progress bar when starting processing."""
	return gr.update(visible=True), gr.update(visible=True, value=0)


	# Main Gradio UI setup
	with gr.Blocks() as demo:
	session_state = gr.State(
	{
	"first_frame": None,
	"all_frames": None,
	"input_points": [],
	"input_labels": [],
	"inference_state": None,
	"frame_stride": 1,
	"scale_factor": 1.0,
	"original_dimensions": None,
	"progress": 0,
	}
	)

	with gr.Column():
	# Title
	gr.Markdown(title)
	with gr.Row():

	with gr.Column():
	# Instructions
	gr.Markdown(description_p)

	with gr.Accordion("Input Video", open=True) as video_in_drawer:
	video_in = gr.Video(label="Input Video", format="mp4")

	with gr.Row():
	point_type = gr.Radio(
	label="point type",
	choices=["include", "exclude"],
	value="include",
	scale=2,
	)
	propagate_btn = gr.Button("Track", scale=1, variant="primary")
	clear_points_btn = gr.Button("Clear Points", scale=1)
	reset_btn = gr.Button("Reset", scale=1)

	points_map = gr.Image(
	label="Frame with Point Prompt", type="numpy", interactive=False
	)

	# Add progress bar
	progress_bar = gr.Slider(
	minimum=0,
	maximum=100,
	value=0,
	step=1,
	label="Processing Progress",
	visible=False,
	interactive=False
	)

	with gr.Column():
	gr.Markdown("# Try some of the examples below ⬇️")
	gr.Examples(
	examples=examples,
	inputs=[
	video_in,
	],
	examples_per_page=5,
	)

	output_image = gr.Image(label="Reference Mask")
	output_video = gr.Video(visible=False)

	# When new video is uploaded
	video_in.upload(
	fn=preprocess_video_in,
	inputs=[
	video_in,
	session_state,
	],
	outputs=[
	video_in_drawer, # Accordion to hide uploaded video player
	points_map, # Image component where we add new tracking points
	output_image,
	output_video,
	progress_bar,
	session_state,
	],
	queue=False,
	)

	video_in.change(
	fn=preprocess_video_in,
	inputs=[
	video_in,
	session_state,
	],
	outputs=[
	video_in_drawer, # Accordion to hide uploaded video player
	points_map, # Image component where we add new tracking points
	output_image,
	output_video,
	progress_bar,
	session_state,
	],
	queue=False,
	)

	# triggered when we click on image to add new points
	points_map.select(
	fn=segment_with_points,
	inputs=[
	point_type, # "include" or "exclude"
	session_state,
	],
	outputs=[
	points_map, # updated image with points
	output_image,
	session_state,
	],
	queue=False,
	)

	# Clear every points clicked and added to the map
	clear_points_btn.click(
	fn=clear_points,
	inputs=session_state,
	outputs=[
	points_map,
	output_image,
	output_video,
	progress_bar,
	session_state,
	],
	queue=False,
	)

	reset_btn.click(
	fn=reset,
	inputs=session_state,
	outputs=[
	video_in,
	video_in_drawer,
	points_map,
	output_image,
	output_video,
	progress_bar,
	session_state,
	],
	queue=False,
	)

	propagate_btn.click(
	fn=update_ui,
	inputs=[],
	outputs=[output_video, progress_bar],
	queue=False,
	).then(
	fn=propagate_to_all,
	inputs=[
	video_in,
	session_state,
	],
	outputs=[
	output_video,
	progress_bar,
	session_state,
	],
	queue=True, # Use queue for CPU processing
	)


	demo.queue()
	demo.launch()