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Aastha

add configurable device support

002cef1 9 months ago

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	import gradio as gr
	import random
	import numpy as np
	import os
	import requests
	import torch
	import torchvision.transforms as T
	from PIL import Image
	from transformers import AutoProcessor, AutoModelForVision2Seq
	import cv2
	import ast
	import torch
	from efficientnet_pytorch import EfficientNet
	from torchvision import transforms
	from PIL import Image
	import gradio as gr
	from super_gradients.training import models


	class Kosmos2:
	def __init__(self):
	self.device = torch.device("cuda" if torch.cuda.is_available() else "cpu")
	self.colors = [
	(0, 255, 0),
	(0, 0, 255),
	(255, 255, 0),
	(255, 0, 255),
	(0, 255, 255),
	(114, 128, 250),
	(0, 165, 255),
	(0, 128, 0),
	(144, 238, 144),
	(238, 238, 175),
	(255, 191, 0),
	(0, 128, 0),
	(226, 43, 138),
	(255, 0, 255),
	(0, 215, 255),
	(255, 0, 0),
	]

	self.color_map = {
	f"{color_id}": f"#{hex(color[2])[2:].zfill(2)}{hex(color[1])[2:].zfill(2)}{hex(color[0])[2:].zfill(2)}" for color_id, color in enumerate(self.colors)
	}

	self.ckpt = "ydshieh/kosmos-2-patch14-224"
	self.model = AutoModelForVision2Seq.from_pretrained(self.ckpt, trust_remote_code=True).to(self.device)
	self.processor = AutoProcessor.from_pretrained(self.ckpt, trust_remote_code=True)

	def is_overlapping(self, rect1, rect2):
	x1, y1, x2, y2 = rect1
	x3, y3, x4, y4 = rect2
	return not (x2 < x3 or x1 > x4 or y2 < y3 or y1 > y4)

	def draw_entity_boxes_on_image(self, image, entities, show=False, save_path=None, entity_index=-1):
	"""_summary_
	Args:
	image (_type_): image or image path
	collect_entity_location (_type_): _description_
	"""
	if isinstance(image, Image.Image):
	image_h = image.height
	image_w = image.width
	image = np.array(image)[:, :, [2, 1, 0]]
	elif isinstance(image, str):
	if os.path.exists(image):
	pil_img = Image.open(image).convert("RGB")
	image = np.array(pil_img)[:, :, [2, 1, 0]]
	image_h = pil_img.height
	image_w = pil_img.width
	else:
	raise ValueError(f"invaild image path, {image}")
	elif isinstance(image, torch.Tensor):
	# pdb.set_trace()
	image_tensor = image.cpu()
	reverse_norm_mean = torch.tensor([0.48145466, 0.4578275, 0.40821073])[:, None, None]
	reverse_norm_std = torch.tensor([0.26862954, 0.26130258, 0.27577711])[:, None, None]
	image_tensor = image_tensor * reverse_norm_std + reverse_norm_mean
	pil_img = T.ToPILImage()(image_tensor)
	image_h = pil_img.height
	image_w = pil_img.width
	image = np.array(pil_img)[:, :, [2, 1, 0]]
	else:
	raise ValueError(f"invaild image format, {type(image)} for {image}")

	if len(entities) == 0:
	return image

	indices = list(range(len(entities)))
	if entity_index >= 0:
	indices = [entity_index]

	# Not to show too many bboxes
	entities = entities[:len(self.color_map)]

	new_image = image.copy()
	previous_bboxes = []
	# size of text
	text_size = 1
	# thickness of text
	text_line = 1 # int(max(1 * min(image_h, image_w) / 512, 1))
	box_line = 3
	(c_width, text_height), _ = cv2.getTextSize("F", cv2.FONT_HERSHEY_COMPLEX, text_size, text_line)
	base_height = int(text_height * 0.675)
	text_offset_original = text_height - base_height
	text_spaces = 3
	# num_bboxes = sum(len(x[-1]) for x in entities)
	used_colors = self.colors # random.sample(colors, k=num_bboxes)

	color_id = -1
	for entity_idx, (entity_name, (start, end), bboxes) in enumerate(entities):
	color_id += 1
	if entity_idx not in indices:
	continue
	for bbox_id, (x1_norm, y1_norm, x2_norm, y2_norm) in enumerate(bboxes):
	# if start is None and bbox_id > 0:
	# color_id += 1
	orig_x1, orig_y1, orig_x2, orig_y2 = int(x1_norm * image_w), int(y1_norm * image_h), int(x2_norm * image_w), int(y2_norm * image_h)

	# draw bbox
	# random color
	color = used_colors[color_id] # tuple(np.random.randint(0, 255, size=3).tolist())
	new_image = cv2.rectangle(new_image, (orig_x1, orig_y1), (orig_x2, orig_y2), color, box_line)

	l_o, r_o = box_line // 2 + box_line % 2, box_line // 2 + box_line % 2 + 1

	x1 = orig_x1 - l_o
	y1 = orig_y1 - l_o

	if y1 < text_height + text_offset_original + 2 * text_spaces:
	y1 = orig_y1 + r_o + text_height + text_offset_original + 2 * text_spaces
	x1 = orig_x1 + r_o

	# add text background
	(text_width, text_height), _ = cv2.getTextSize(f" {entity_name}", cv2.FONT_HERSHEY_COMPLEX, text_size, text_line)
	text_bg_x1, text_bg_y1, text_bg_x2, text_bg_y2 = x1, y1 - (text_height + text_offset_original + 2 * text_spaces), x1 + text_width, y1

	for prev_bbox in previous_bboxes:
	while self.is_overlapping((text_bg_x1, text_bg_y1, text_bg_x2, text_bg_y2), prev_bbox):
	text_bg_y1 += (text_height + text_offset_original + 2 * text_spaces)
	text_bg_y2 += (text_height + text_offset_original + 2 * text_spaces)
	y1 += (text_height + text_offset_original + 2 * text_spaces)

	if text_bg_y2 >= image_h:
	text_bg_y1 = max(0, image_h - (text_height + text_offset_original + 2 * text_spaces))
	text_bg_y2 = image_h
	y1 = image_h
	break

	alpha = 0.5
	for i in range(text_bg_y1, text_bg_y2):
	for j in range(text_bg_x1, text_bg_x2):
	if i < image_h and j < image_w:
	if j < text_bg_x1 + 1.35 * c_width:
	# original color
	bg_color = color
	else:
	# white
	bg_color = [255, 255, 255]
	new_image[i, j] = (alpha * new_image[i, j] + (1 - alpha) * np.array(bg_color)).astype(np.uint8)

	cv2.putText(
	new_image, f" {entity_name}", (x1, y1 - text_offset_original - 1 * text_spaces), cv2.FONT_HERSHEY_COMPLEX, text_size, (0, 0, 0), text_line, cv2.LINE_AA
	)
	# previous_locations.append((x1, y1))
	previous_bboxes.append((text_bg_x1, text_bg_y1, text_bg_x2, text_bg_y2))

	pil_image = Image.fromarray(new_image[:, :, [2, 1, 0]])
	if save_path:
	pil_image.save(save_path)
	if show:
	pil_image.show()

	return pil_image

	def generate_predictions(self, image_input, text_input):

	# Save the image and load it again to match the original Kosmos-2 demo.
	# (https://github.com/microsoft/unilm/blob/f4695ed0244a275201fff00bee495f76670fbe70/kosmos-2/demo/gradio_app.py#L345-L346)
	user_image_path = "/tmp/user_input_test_image.jpg"
	image_input.save(user_image_path)
	# This might give different results from the original argument `image_input`
	image_input = Image.open(user_image_path)

	if text_input == "Brief":
	text_input = "<grounding>An image of"
	elif text_input == "Detailed":
	text_input = "<grounding>Describe this image in detail:"
	else:
	text_input = f"<grounding>{text_input}"

	inputs = self.processor(text=text_input, images=image_input, return_tensors="pt")

	generated_ids = self.model.generate(
	pixel_values=inputs["pixel_values"].to(self.device),
	input_ids=inputs["input_ids"][:, :-1].to(self.device),
	attention_mask=inputs["attention_mask"][:, :-1].to(self.device),
	img_features=None,
	img_attn_mask=inputs["img_attn_mask"][:, :-1].to(self.device),
	use_cache=True,
	max_new_tokens=128,
	)
	generated_text = self.processor.batch_decode(generated_ids, skip_special_tokens=True)[0]

	# By default, the generated text is cleanup and the entities are extracted.
	processed_text, entities = self.processor.post_process_generation(generated_text)

	annotated_image = self.draw_entity_boxes_on_image(image_input, entities, show=False)

	color_id = -1
	entity_info = []
	filtered_entities = []
	for entity in entities:
	entity_name, (start, end), bboxes = entity
	if start == end:
	# skip bounding bbox without a `phrase` associated
	continue
	color_id += 1
	# for bbox_id, _ in enumerate(bboxes):
	# if start is None and bbox_id > 0:
	# color_id += 1
	entity_info.append(((start, end), color_id))
	filtered_entities.append(entity)

	colored_text = []
	prev_start = 0
	end = 0
	for idx, ((start, end), color_id) in enumerate(entity_info):
	if start > prev_start:
	colored_text.append((processed_text[prev_start:start], None))
	colored_text.append((processed_text[start:end], f"{color_id}"))
	prev_start = end

	if end < len(processed_text):
	colored_text.append((processed_text[end:len(processed_text)], None))

	return annotated_image, colored_text, str(filtered_entities)

	class VehiclePredictor:
	def __init__(self, model_path):
	self.device = torch.device("cuda" if torch.cuda.is_available() else "cpu")
	self.yolo_nas_l = models.get("yolo_nas_l", pretrained_weights="coco")
	self.classifier_model = torch.load(model_path)
	self.classifier_model = self.classifier_model.to(self.device)
	self.classifier_model.eval() # Set the model to evaluation mode

	def bounding_boxes_overlap(self, box1, box2):
	"""Check if two bounding boxes overlap or touch."""
	x1, y1, x2, y2 = box1
	x3, y3, x4, y4 = box2
	return not (x3 > x2 or x4 < x1 or y3 > y2 or y4 < y1)

	def merge_boxes(self, box1, box2):
	"""Return the encompassing bounding box of two boxes."""
	x1, y1, x2, y2 = box1
	x3, y3, x4, y4 = box2
	x = min(x1, x3)
	y = min(y1, y3)
	w = max(x2, x4)
	h = max(y2, y4)
	return (x, y, w, h)

	def save_merged_boxes(self, predictions, image_np):
	"""Save merged bounding boxes as separate images."""
	processed_boxes = set()
	roi = None # Initialize roi to None

	for image_prediction in predictions:
	bboxes = image_prediction.prediction.bboxes_xyxy
	for box1 in bboxes:
	for box2 in bboxes:
	if np.array_equal(box1, box2):
	continue
	if self.bounding_boxes_overlap(box1, box2) and tuple(box1) not in processed_boxes and tuple(box2) not in processed_boxes:
	merged_box = self.merge_boxes(box1, box2)
	roi = image_np[int(merged_box[1]):int(merged_box[3]), int(merged_box[0]):int(merged_box[2])]
	processed_boxes.add(tuple(box1))
	processed_boxes.add(tuple(box2))
	break # Exit the inner loop once a match is found
	if roi is not None:
	break # Exit the outer loop once a match is found
	return roi

	# Perform inference on an image
	def predict_image(self, image, model):
	# First, get the ROI using YOLO-NAS
	image_np = cv2.cvtColor(np.array(image), cv2.COLOR_RGB2BGR)
	predictions = self.yolo_nas_l.predict(image_np, iou=0.3, conf=0.35)
	roi_new = self.save_merged_boxes(predictions, image_np)

	if roi_new is None:
	roi_new = image_np # Use the original image if no ROI is found

	# Convert ROI back to PIL Image for EfficientNet
	roi_image = Image.fromarray(cv2.cvtColor(roi_new, cv2.COLOR_BGR2RGB))

	# Define the image transformations
	transform = transforms.Compose([
	transforms.Resize(256),
	transforms.CenterCrop(224),
	transforms.ToTensor(),
	transforms.Normalize([0.485, 0.456, 0.406], [0.229, 0.224, 0.225])
	])

	# Convert PIL Image to Tensor
	roi_image_tensor = transform(roi_image).unsqueeze(0).to(self.device)

	with torch.no_grad():
	outputs = self.classifier_model(roi_image_tensor)
	_, predicted = outputs.max(1)
	prediction_text = 'Accident' if predicted.item() == 0 else 'No accident'

	return roi_image, prediction_text # Return both the roi_image and the prediction text


	def main():
	kosmos2 = Kosmos2()
	vehicle_predictor = VehiclePredictor('vehicle.pt')

	with gr.Blocks(title="Advanced Vehicle Contextualization & Collision Prediction", theme=gr.themes.Base()).queue() as demo:
	gr.Markdown(("""
	# Models used -
	Kosmos-2: Grounding Multimodal Large Language Models to the World
	[[Paper]](https://arxiv.org/abs/2306.14824) [[Code]](https://github.com/microsoft/unilm/blob/master/kosmos-2)
	YOLO-NAS [[Code]](https://github.com/Deci-AI/super-gradients/blob/master/YOLONAS.md)
	EfficientNet-b0
	"""))
	with gr.Row():
	with gr.Column():
	image_input = gr.Image(type="pil", label="Test Image")
	text_input = gr.Radio(["Brief", "Detailed"], label="Description Type", value="Brief")
	run_button = gr.Button(label="Run", visible=True)

	with gr.Column():
	image_output_kosmos = gr.Image(type="pil", label="Kosmos-2 Output Image")
	text_output_kosmos = gr.HighlightedText(
	label="Generated Description by Kosmos-2",
	combine_adjacent=False,
	show_legend=True,
	).style(color_map=kosmos2.color_map)

	image_output_vehicle = gr.Image(type="pil", label="Collision Predictor Output Image", size=(112, 112))
	text_output_vehicle = gr.Textbox(label="Collision Predictor Result")

	# record which text span (label) is selected
	selected = gr.Number(-1, show_label=False, placeholder="Selected", visible=False)

	# record the current `entities`
	entity_output = gr.Textbox(visible=False)

	# get the current selected span label
	def get_text_span_label(evt: gr.SelectData):
	if evt.value[-1] is None:
	return -1
	return int(evt.value[-1])
	# and set this information to `selected`
	text_output_kosmos.select(get_text_span_label, None, selected)

	# update output image when we change the span (enity) selection
	def update_output_image(img_input, image_output, entities, idx):
	entities = ast.literal_eval(entities)
	updated_image = kosmos2.draw_entity_boxes_on_image(img_input, entities, entity_index=idx)
	return updated_image
	selected.change(update_output_image, [image_input, image_output_kosmos, entity_output, selected], [image_output_kosmos])

	def combined_predictions(img, description_type):
	# Kosmos2 predictions
	kosmos_image, kosmos_text, entities = kosmos2.generate_predictions(img, description_type)

	# VehiclePredictor predictions
	vehicle_image, vehicle_text = vehicle_predictor.predict_image(img, vehicle_predictor.classifier_model)

	return kosmos_image, kosmos_text, entities, vehicle_image, vehicle_text

	run_button.click(fn=combined_predictions,
	inputs=[image_input, text_input],
	outputs=[image_output_kosmos, text_output_kosmos, entity_output, image_output_vehicle, text_output_vehicle],
	show_progress=True, queue=True)

	demo.launch(share=True)

	if __name__ == "__main__":
	main()