163 lines
5.3 KiB
Python
163 lines
5.3 KiB
Python
from operator import itemgetter
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from PIL import Image, ImageTk
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import math
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from dataclasses import dataclass
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import numpy as np
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import cv2
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from pathlib import Path
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dir_path = Path(".").absolute()
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TYPE_1 = "_________"
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TYPE_2 = "___ ___"
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import cv2
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def capture_frame_from_webcam():
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"""
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Captures a single frame from the webcam.
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Returns:
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frame (numpy.ndarray): The captured frame as a NumPy array.
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"""
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# Open a connection to the default webcam (index 0)
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cap = cv2.VideoCapture(0)
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if not cap.isOpened():
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raise Exception("Could not open webcam. Please check your webcam connection.")
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try:
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# Capture a single frame
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ret, frame = cap.read()
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if not ret:
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raise Exception("Failed to capture frame from webcam.")
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return frame
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finally:
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# Release the webcam resource
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cap.release()
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@dataclass
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class Object:
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x: int
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y: int
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rayon: int
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def process_frame(params):
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"""
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Simulates OpenCV processing using parameters from the GUI.
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Args:
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params (dict): A dictionary of variable values passed from the GUI.
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Returns:
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ImageTk.PhotoImage: A Tkinter-compatible image.
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str: A result text description.
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"""
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# Simulate processing: for now, return a dummy image and text.
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# width, height = 400, 300
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# image = Image.new("RGB", (width, height),
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# color=(params["color1_R_min"] * 4, params["color1_V_min"] * 4, params["color1_B_min"] * 4))
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# image_tk = ImageTk.PhotoImage(image)
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#
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# result_text = f"Processed image with params: {params}"
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# return image_tk, result_text
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(minDist, param1, param2, minRadius, maxRadius,
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color1_R_min, color1_V_min, color1_B_min, color1_R_max, color1_V_max, color1_B_max) = itemgetter(
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'minDist', 'param1', 'param2', 'minRadius', 'maxRadius',
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'color1_R_min', 'color1_V_min', 'color1_B_min', 'color1_R_max', 'color1_V_max', 'color1_B_max'
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)(params)
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# 1. Acquisition de l'image
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# src = dir_path.joinpath('tests/images/balls-full-small.jpg')
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# raw_image = cv2.imread(str(src))
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raw_image = capture_frame_from_webcam()
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# 2. Boxing des objets via opencv
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gray = cv2.cvtColor(raw_image, cv2.COLOR_BGR2GRAY)
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blurred = cv2.medianBlur(gray, 25)
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circles = cv2.HoughCircles(blurred, cv2.HOUGH_GRADIENT, 1, minDist, param1=param1, param2=param2,
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minRadius=minRadius,
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maxRadius=maxRadius)
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min_rayon = 9999
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cochonnet = None
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boules = []
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if circles is not None:
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circles = np.uint16(np.around(circles))
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for i in circles[0, :]:
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boule = Object(x=int(i[0]), y=int(i[1]), rayon=int(i[2]))
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# 3. Détection de la box la plus petite : cochonnet
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if boule.rayon < min_rayon:
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min_rayon = boule.rayon
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if cochonnet is not None:
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boules.append(cochonnet)
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cochonnet = boule
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else:
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boules.append(boule)
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# 4. Regroupement en liste de boules 1 ou 2 selon la couleur principale de chaque box restante
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hsv = cv2.cvtColor(raw_image, cv2.COLOR_BGR2HSV)
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(h, s, v) = cv2.split(hsv)
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s = s * 2
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s = np.clip(s, 0, 255)
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imghsv = cv2.merge([h, s, v])
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boules_couleurs = []
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boules_bgr = []
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for boule in boules:
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half_diametre = int(boule.rayon / 2)
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crop = imghsv[
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boule.y - half_diametre:boule.y + half_diametre,
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boule.x - half_diametre:boule.x + half_diametre,
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].copy()
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pixels = np.float32(crop.reshape(-1, 3))
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n_colors = 2
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criteria = (cv2.TERM_CRITERIA_EPS + cv2.TERM_CRITERIA_MAX_ITER, 200, .1)
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_, labels, palette = cv2.kmeans(pixels, n_colors, None, criteria, 10, cv2.KMEANS_RANDOM_CENTERS)
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_, counts = np.unique(labels, return_counts=True)
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(b, v, r) = palette[np.argmax(counts)]
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boules_bgr.append(f"R:{int(r)} V:{int(v)} B:{int(b)}")
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# On récupère les valeurs de R G et B qui sont à analyser
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if int(
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color1_R_min <= math.floor(r) <= color1_R_max
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and color1_V_min <= math.floor(v) <= color1_V_max
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and color1_B_min <= math.floor(b) <= color1_B_max
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):
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boules_couleurs.append(TYPE_1)
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else :
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boules_couleurs.append(TYPE_2)
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# 5. Calcul des distances entre chaque boule et le cochonnet selon le centre des boxs
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boules_distance = {}
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for i, boule in enumerate(boules):
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dist = int(math.sqrt(math.pow(cochonnet.x - boule.x, 2) + math.pow(cochonnet.y - boule.y, 2)))
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boules_distance[i] = dist
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boules_distance = dict(sorted(boules_distance.items(), key=lambda item: item[1]))
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# 6. Liste ordonnée des 6 distances les plus faibles
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boules_proches = [x for x in list(boules_distance)[0:6]]
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# 7. Sortie des 6 couleurs en --- ou - -
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return_text = ""
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img_final = raw_image.copy()
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for i in boules_proches:
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boule = boules[i]
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return_text += f"{boules_couleurs[i]}\n"
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cv2.circle(img_final, (boule.x, boule.y), boule.rayon, (0, 255, 0), 2)
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cv2.putText(img_final, boules_bgr[i], (boule.x, boule.y), cv2.FONT_HERSHEY_SIMPLEX,
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fontScale=0.75, color=(255, 255, 255), thickness=1, lineType=cv2.LINE_AA)
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return img_final, return_text
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