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import vgg16 | |
import numpy as np | |
def cosine_similarity(vector1, vector2): | |
# # 计算向量的点积 | |
# dot_product = np.dot(vector1, vector2) | |
# # 计算向量的模长 | |
# magnitude_vector1 = np.linalg.norm(vector1) | |
# magnitude_vector2 = np.linalg.norm(vector2) | |
# # 计算余弦相似度 | |
# return dot_product / (magnitude_vector1 * magnitude_vector2) | |
flat_vector1 = vector1.reshape(-1) | |
flat_vector2 = vector2.reshape(-1) | |
dot_product = np.dot(flat_vector1, flat_vector2) | |
norm_vector1 = np.linalg.norm(flat_vector1) | |
norm_vector2 = np.linalg.norm(flat_vector2) | |
return dot_product / (norm_vector1 * norm_vector2) | |
def cal_compatibility(): | |
n = 4096 | |
access_feature = [] | |
cloth_feature = [] | |
for item_id in range(1, 9): | |
access_feature.append(vgg16.extract_features('downloads/access_' + '%s.jpg' % item_id)[0]) | |
for item_id in range(1, 7): | |
cloth_feature.append(vgg16.extract_features('downloads/gen_cloth_' + '%s.jpeg' % item_id)[0]) | |
best_score = float('-inf') | |
best_cloth = 0 | |
best_access = 0 | |
for i in range(1, 9): | |
for j in range(1, 7): | |
score = cosine_similarity(access_feature[i - 1], cloth_feature[j - 1]) | |
if score > best_score: | |
best_score = score | |
best_cloth = j | |
best_access = i | |
print(best_cloth, best_access) | |
picture = [f"downloads/gen_cloth_{best_cloth}.jpeg", f"downloads/access_{best_access}.jpg"] | |
return picture | |