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- import numpy as np
- import pandas
- import csv
- import order_bounding_boxes_in_each_block
- from sklearn.cluster import DBSCAN
- from sklearn import metrics
- from sklearn.datasets.samples_generator import make_blobs
- from sklearn.preprocessing import StandardScaler
- def my_distance(x,y):
- blub = "ddd"
- return blub
- def cluster(file_in, file_out):
- # #############################################################################
- data_df = pandas.read_csv("/home/bscheibel/PycharmProjects/dxf_reader/temporary/list_to_csv_with_avg_points.csv", sep=";")
- data_df.head(3)
- data = data_df[["xavg_elem","yavg_elem","ausrichtung"]]
- #print(data)
- data = StandardScaler().fit_transform(data)
- # #############################################################################
- # Compute DBSCAN
- db = DBSCAN(eps=0.075, min_samples=1, metric="euclidean").fit(data)
- #core_samples_mask = np.zeros_like(db.labels_, dtype=bool)
- #core_samples_mask[db.core_sample_indices_] = True
- labels = db.labels_
- print(data[labels == 0])
- data_df["cluster"] = labels
- # Number of clusters in labels, ignoring noise if present.
- n_clusters_ = len(set(labels)) - (1 if -1 in labels else 0)
- n_noise_ = list(labels).count(-1)
- print('Estimated number of clusters: %d' % n_clusters_)
- print('Estimated number of noise points: %d' % n_noise_)
- print("Silhouette Coefficient: %0.3f"
- % metrics.silhouette_score(data, labels))
- # #############################################################################
- # Plot result
- """ort matplotlib.pyplot as plt
- # Black removed and is used for noise instead.
- unique_labels = set(labels)
- colors = [plt.cm.Spectral(each)
- for each in np.linspace(0, 1, len(unique_labels))]
- for k, col in zip(unique_labels, colors):
- if k == -1:
- # Black used for noise.
- col = [0, 0, 0, 1]
- class_member_mask = (labels == k)
- xy = data[class_member_mask & core_samples_mask]
- plt.plot(xy[:, 0], xy[:, 1], 'o', markerfacecolor=tuple(col),
- markeredgecolor='k', markersize=14)
- xy = data[class_member_mask & ~core_samples_mask]
- plt.plot(xy[:, 0], xy[:, 1], 'o', markerfacecolor=tuple(col),
- markeredgecolor='k', markersize=6)
- plt.title('Estimated number of clusters: %d' % n_clusters_)
- plt.show()"""
- #print(data_df.head(3))
- #data_df.to_csv("values_clusteredfromPDF_GV12.csv")
- data_df.groupby('cluster')['element'].apply(' '.join).reset_index().to_csv("values_clusteredfromHTML_layout_LH.csv",sep=";")
- def get_average_xy(list_input):
- csv_name = "temporary/list_to_csv_with_avg_points.csv"
- new_list = []
- resultFile = open(csv_name, 'w')
- wr = csv.writer(resultFile, delimiter=";")
- wr.writerow(["element", "xavg_elem","yavg_elem", "ausrichtung"])
- for element in list_input:
- xavg_elem = 0
- yavg_elem = 0
- y_min = 1000000
- y_max = 0
- x_min = 1000000
- x_max = 0
- for blub in element:
- xavg_elem += (float(blub[0]) + float(blub[2]))/2
- yavg_elem += (float(blub[1]) + float(blub[3]))/2
- if float(blub[1]) < y_min:
- y_min = float(blub[1])
- #print("y_min:",y_min)
- if float(blub[0]) < x_min:
- x_min = float(blub[0])
- if float(blub[3]) > y_max:
- y_max = float(blub[3])
- if float(blub[2]) > x_max:
- x_max = float(blub[2])
- if x_max-x_min > y_max-y_min:
- ausrichtung = 0
- else:
- ausrichtung = 1
- xavg_elem = xavg_elem/len(element)
- #print(xavg_elem)
- yavg_elem = yavg_elem/len(element)
- #element.extend([xavg_elem, yavg_elem])
- #print(element)
- #new_list.append(element)
- wr.writerow([element,xavg_elem,yavg_elem, ausrichtung])
- resultFile.close()
- #print(new_list)
- return csv_name
- #cluster(33,33)
- file = "/home/bscheibel/PycharmProjects/dxf_reader/drawings/5152166_Rev04.html"
- #file = "/home/bscheibel/PycharmProjects/dxf_reader/drawings/5129275_Rev01-GV12.html"
- #result = order_bounding_boxes_in_each_block.get_bound_box(file)
- #get_average_xy(result)
- cluster(33,33)
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