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Sign-Language-Interpreter / app.py
HuggingFace-SK
use flask api instead of socket io
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 import cv2
import base64
import numpy as np
import io
from flask import Flask, render_template, Response, request, jsonify
from flask_socketio import SocketIO, emit
from PIL import Image
from time import time as unix_time
import os
import mediapipe as mp
from mediapipe.tasks import python
from mediapipe.tasks.python import vision
import time
import argparse
from mediapipe.framework.formats import landmark_pb2
from mediapipe import solutions
from tflite_support.task import vision as vision2
from tflite_support.task import core
from tflite_support.task import processor
from numpy.linalg import norm
#Image Annotation Utils
char_list=[]
global letter_result
letter_result = 0
global old_letter_result
old_letter_result = 0
MARGIN = 10 # pixels
FONT_SIZE = 1
FONT_THICKNESS = 1
HANDEDNESS_TEXT_COLOR = (88, 205, 54) # vibrant green
global test_x
global test_y
global result_to_show
result_to_show=0
global cresult_to_show
cresult_to_show=0
text_x = 0
text_y = 0
cwhich=0
lastwidth = 400
letterscore=0
frame_time=0
same_letter_time=0
no_hand_flag=1
# UTILS
def brightness(img):
if len(img.shape) == 3:
# Colored RGB or BGR (*Do Not* use HSV images with this function)
# create brightness with euclidean norm
return np.average(norm(img, axis=2)) / np.sqrt(3)
else:
# Grayscale
return np.average(img)
def draw_landmarks_on_image(rgb_image, detection_result):
hand_landmarks_list = detection_result.hand_landmarks
handedness_list = detection_result.handedness
annotated_image = np.copy(rgb_image)
crop = []
image_height, image_width, image_heightgray=annotated_image.shape
# Loop through the detected hands to visualize.
for idx in range(len(hand_landmarks_list)):
hand_landmarks = hand_landmarks_list[idx]
handedness = handedness_list[idx]
# Draw the hand landmarks.
hand_landmarks_proto = landmark_pb2.NormalizedLandmarkList()
hand_landmarks_proto.landmark.extend([
landmark_pb2.NormalizedLandmark(x=landmark.x, y=landmark.y, z=landmark.z) for landmark in hand_landmarks
])
solutions.drawing_utils.draw_landmarks(
annotated_image,
hand_landmarks_proto,
solutions.hands.HAND_CONNECTIONS,
solutions.drawing_styles.get_default_hand_landmarks_style(),
solutions.drawing_styles.get_default_hand_connections_style())
# Get bounding box
height, width, _ = annotated_image.shape
x_coordinates = [landmark.x for landmark in hand_landmarks]
y_coordinates = [landmark.y for landmark in hand_landmarks]
min_x = int(min(x_coordinates) * width) # Left
min_y = int(min(y_coordinates) * height) # Top
max_x = int(max(x_coordinates) * width) # Right
max_y = int(max(y_coordinates) * height) # Bottom
#Get dimensions of bounding box
sect_height = max_y-(min_y)
sect_width = max_x-(min_x)
#Get center of bounding box
center_x=(min_x+max_x)/2
center_y=(min_y+max_y)/2
sect_diameter=50
#Define dominant axis for aspect ratio
if(sect_height>sect_width):
sect_diameter = sect_height
if(sect_height<sect_width):
sect_diameter = sect_width
sect_diameter=sect_diameter+50 # Pad diameter
sect_radius=int(sect_diameter/2) # Find radius
#Crop Image
crop_top=int(center_y-sect_radius) #Top boundry
crop_bottom=int(center_y+sect_radius) #Bottom boundry
crop_left=int(center_x-sect_radius) #Left boundry
crop_right=int(center_x+sect_radius) #Right boundry
#Account for out of canvas
if(crop_top<0): #Bounding box too high
crop_top=0
if(crop_left<0): #Bounding box too far left
crop_left=0
if(crop_right>image_width): #Bounding box too far right
crop_right=image_width
if(crop_bottom>image_height): #Bounding box too low
crop_bottom=image_height
# Trace bounding box
annotated_image = cv2.rectangle(annotated_image, (crop_left, crop_top), (crop_right, crop_bottom), (255,0,0), 6)
global text_x
global text_y
# For text, currently not used
text_x=crop_left
text_y=crop_top
# Get cropped image
crop = annotated_image[crop_top:crop_bottom, crop_left:crop_right]
# Scale cropped image
h, w = crop.shape[0:2]
neww = 150
newh = int(neww*(h/w))
crop = cv2.resize(crop, (neww, newh))
#annotated_image[0:0+crop.shape[0], 0:0+crop.shape[1]] = crop # Used for superimposition
#annotated_image=crop # Used for replacement
return [annotated_image, crop]
#-------------------------------------------------------------
# Letter List
letter_list=["A","B","C","D","E","F","G","H","I","J","K","L","M","N","O","P","Q","R","S","T","U","V","W","X","Y","Z","#"]
# Initialise MediaPipe hand landmark detction
RESULT = None
BaseOptions = mp.tasks.BaseOptions
HandLandmarker = mp.tasks.vision.HandLandmarker
HandLandmarkerOptions = mp.tasks.vision.HandLandmarkerOptions
HandLandmarkerResult = mp.tasks.vision.HandLandmarkerResult
VisionRunningMode = mp.tasks.vision.RunningMode
cbase_options = core.BaseOptions(file_name="./better_exported/model.tflite") # New tflite
ccbase_options = core.BaseOptions(file_name="./exported/model.tflite") # Old tflite
# Initialise ASL tflite model
cclassification_options = processor.ClassificationOptions(max_results=1)
coptions = vision2.ImageClassifierOptions(base_options=cbase_options, classification_options=cclassification_options)
ccoptions = vision2.ImageClassifierOptions(base_options=ccbase_options, classification_options=cclassification_options)
cclassifier = vision2.ImageClassifier.create_from_options(coptions)
ccclassifier = vision2.ImageClassifier.create_from_options(ccoptions)
def print_result(result: HandLandmarkerResult, output_image: mp.Image, timestamp_ms: int):
global RESULT
RESULT=result
options = HandLandmarkerOptions(
base_options=BaseOptions(model_asset_path='hand_landmarker.task'),
running_mode=VisionRunningMode.LIVE_STREAM,
result_callback=print_result)
detector = vision.HandLandmarker.create_from_options(options)
video_frames=[]
app = Flask(__name__)
@app.route('/')
def index():
return render_template('index.html')
@app.route('/api/data', methods=['POST'])
def handle_video_frame():
frame = request.json.get('key')
#print(request.json)
response_frame = data_uri_to_image(frame)
decimg = response_frame
#--------------------------------------------
mp_image = mp.Image(image_format=mp.ImageFormat.SRGB, data=decimg) # Create MediaPipe image
#print(mp.Timestamp.from_seconds(time.time()).value)
detection_result = detector.detect_async(mp_image, mp.Timestamp.from_seconds(time.time()).value) # detct
# Try-Catch block, because detection is not done during model initialisation
global no_hand_flag, frame_time, same_letter_time, letter_result, old_letter_result, char_list, letterscore
try:
result_images = draw_landmarks_on_image(mp_image.numpy_view(), RESULT) # Array of annotated and cropped images
annotated_image = result_images[0]
cropped_image = result_images[1]
#Standardise and fit shape by resizing
h, w = annotated_image.shape[0:2]
neww = 500
newh = int(neww*(h/w))
resized_image = cv2.resize(annotated_image, (neww, newh))
final_image=resized_image
if(RESULT.handedness != []): # To chack if there is any result at all and then feed tflite model
no_hand_flag=0
if RESULT.handedness[0][0].display_name == 'Right':
tf_image = vision2.TensorImage.create_from_array(cropped_image)
classification_result = cclassifier.classify(tf_image) # New
cclassification_result = ccclassifier.classify(tf_image) # Old
result_to_show = classification_result.classifications[0].categories[0].category_name # New
cresult_to_show = cclassification_result.classifications[0].categories[0].category_name # Old
if cclassification_result.classifications[0].categories[0].score > classification_result.classifications[0].categories[0].score:
letter_result = cresult_to_show # To implement further UX with Text to Speech
cwhich="Old"
if result_to_show == "P" and cresult_to_show !="P":
cwhich="New"
letter_result = result_to_show
else:
letter_result = result_to_show # To implement further UX with Text to Speech
cwhich="New"
if cresult_to_show == "M" and cresult_to_show !="M":
cwhich="Old"
if result_to_show != "R" and cresult_to_show =="R":
cwhich="Old"
letter_result = cresult_to_show
if result_to_show != "T" and cresult_to_show =="T":
cwhich="Old"
letter_result = cresult_to_show
if cwhich=="Old" :
letterscore = cclassification_result.classifications[0].categories[0].score
if cwhich=="New" :
letterscore = classification_result.classifications[0].categories[0].score
else:
tf_image = vision2.TensorImage.create_from_array(cropped_image)
classification_result = cclassifier.classify(tf_image) # New
result_to_show = classification_result.classifications[0].categories[0].category_name # New
if result_to_show != "B":
letter_result='_'
else:
letter_result='>'
except Exception as e:
# Ha! The catch err{throw err} scenario, it was actually quite useful in debugging though
print(e)
frame_data = image_to_data_uri(final_image)
#print(frame_data)
return jsonify({"result": letter_result, "frame": frame_data}), 200
def data_uri_to_image(data_uri):
header, encoded = data_uri.split(',', 1)
decoded_data = base64.b64decode(encoded)
nparr = np.frombuffer(decoded_data, np.uint8)
image = cv2.imdecode(nparr, cv2.IMREAD_COLOR)
return image
def image_to_data_uri(image):
# Encode the image as a JPEG
_, buffer = cv2.imencode('.jpg', image)
# Convert the buffer to bytes
image_bytes = buffer.tobytes()
# Encode the bytes to Base64
base64_encoded = base64.b64encode(image_bytes).decode('utf-8')
# Create the Data URI
data_uri = f"data:image/jpeg;base64,{base64_encoded}"
return data_uri
if (__name__ == '__main__'):
app.run( host='0.0.0.0', port=7860)