import random from itertools import combinations import numpy as np from osdsynth.processor.pointcloud import calculate_distances_between_point_clouds, human_like_distance # from osdsynth.processor.prompt_template import * from osdsynth.processor.prompt_utils import * # from osdsynth.processor.prompt_spatitalbench_template import * from osdsynth.processor.prompt import * def get_upper(theta): for i in [-1,0,1,2]: if theta < i * np.pi / 2 - np.pi / 4: return i * np.pi / 2 - np.pi / 4 return 3 * np.pi / 2 - np.pi / 4 def CR_two_front(A, B): A_desc, A_cloud = A["caption"], A["pcd"] A_desc = A_desc.lower() B_desc, B_cloud = B["caption"], B["pcd"] B_desc = B_desc.lower() # 从PyTorch3D的坐标系转换到OpenCV的坐标系 A_pos = A_cloud.get_center() A_pos[0] = -A_pos[0]; A_pos[1] = -A_pos[1] B_pos = B_cloud.get_center() B_pos[0] = -B_pos[0]; B_pos[1] = -B_pos[1] A_rotation_matrix = A["rotation_matrix"] B_rotation_matrix = B["rotation_matrix"] B_rotation_matrix = A_rotation_matrix.T @ B_rotation_matrix # 在A的坐标系下,B的旋转矩阵 A_P_B = A_rotation_matrix.T @ (B_pos - A_pos) # 在A的坐标系下,B相对于A的位置 A_P_B_last = A['A_P_B'] theta1 = np.arctan2(A_P_B[2], A_P_B[0]) theta2 = np.arctan2(A_P_B_last[2], A_P_B_last[0]) theta1_upper = get_upper(theta1) if theta1_upper < np.pi and theta1_upper > -np.pi/2: theta1_lower = theta1_upper - np.pi / 2 position = True if theta1_upper > theta2 > theta1_lower else False else: # 135~180和-180~-135的情况 position = True if theta2 < -3/4*np.pi or theta2 > 3/4*np.pi else False max_angle = 30 angle_rad_A = np.arccos(np.clip(np.dot(A_rotation_matrix.T[0], np.array([0,0,-1])), -1.0, 1.0)) direction = angle_rad_A < max_angle / 180 * np.pi check = position and direction question_template = f"Are [A] and [B] maintaining their original relative relationship when viewed from the front of [A]?" question = question_template.replace("[A]", A_desc).replace("[B]", B_desc) answer = "Yes" if check else "No" score = 0 if check: score = 1 else: if position: w1 = 1 else: if theta1_upper < np.pi and theta1_upper > -np.pi/2: w1 = 1 - np.min([np.abs(theta1_upper-theta2), np.abs(theta2-theta1_lower)]) / (np.pi / 6) # 30度的阈值 else: # 135~180和-180~-135的情况 theta2 = theta2 + 2 * np.pi if theta2 < -3/4*np.pi else theta2 # 转化到0~2pi w1 = 1 - np.min([np.abs(1.25*np.pi-theta2), np.abs(theta2-0.75*np.pi)]) / (np.pi / 6) # 30度的阈值 if direction: w2 = 1 else: w2 = 1 - np.abs(angle_rad_A - max_angle / 180 * np.pi) / (np.pi / 6) # 30度的阈值 score = 0 if w1<0 or w2<0 else w1 * w2 return question, answer, check, score def CR_two_back(A, B): A_desc, A_cloud = A["caption"], A["pcd"] A_desc = A_desc.lower() B_desc, B_cloud = B["caption"], B["pcd"] B_desc = B_desc.lower() # 从PyTorch3D的坐标系转换到OpenCV的坐标系 A_pos = A_cloud.get_center() A_pos[0] = -A_pos[0]; A_pos[1] = -A_pos[1] B_pos = B_cloud.get_center() B_pos[0] = -B_pos[0]; B_pos[1] = -B_pos[1] A_rotation_matrix = A["rotation_matrix"] B_rotation_matrix = B["rotation_matrix"] B_rotation_matrix = A_rotation_matrix.T @ B_rotation_matrix # 在A的坐标系下,B的旋转矩阵 A_P_B = A_rotation_matrix.T @ (B_pos - A_pos) # 在A的坐标系下,B相对于A的位置 A_P_B_last = A['A_P_B'] theta1 = np.arctan2(A_P_B[2], A_P_B[0]) theta2 = np.arctan2(A_P_B_last[2], A_P_B_last[0]) theta1_upper = get_upper(theta1) if theta1_upper < np.pi and theta1_upper > -np.pi/2: theta1_lower = theta1_upper - np.pi / 2 position = True if theta1_upper > theta2 > theta1_lower else False else: # 135~180和-180~-135的情况 position = True if theta2 < -3/4*np.pi or theta2 > 3/4*np.pi else False max_angle = 30 angle_rad_A = np.arccos(np.clip(np.dot(A_rotation_matrix.T[0], np.array([0,0,1])), -1.0, 1.0)) direction = angle_rad_A < max_angle / 180 * np.pi check = position and direction question_template = f"Are [A] and [B] maintaining their original relative relationship when viewed from the back of [A]?" question = question_template.replace("[A]", A_desc).replace("[B]", B_desc) answer = "Yes" if check else "No" score = 0 if check: score = 1 else: if position: w1 = 1 else: if theta1_upper < np.pi and theta1_upper > -np.pi/2: w1 = 1 - np.min([np.abs(theta1_upper-theta2), np.abs(theta2-theta1_lower)]) / (np.pi / 6) # 30度的阈值 else: # 135~180和-180~-135的情况 theta2 = theta2 + 2 * np.pi if theta2 < -3/4*np.pi else theta2 # 转化到0~2pi w1 = 1 - np.min([np.abs(1.25*np.pi-theta2), np.abs(theta2-0.75*np.pi)]) / (np.pi / 6) # 30度的阈值 if direction: w2 = 1 else: w2 = 1 - np.abs(angle_rad_A - max_angle / 180 * np.pi) / (np.pi / 6) # 30度的阈值 score = 0 if w1<0 or w2<0 else w1 * w2 return question, answer, check, score def CR_two_left(A, B): A_desc, A_cloud = A["caption"], A["pcd"] A_desc = A_desc.lower() B_desc, B_cloud = B["caption"], B["pcd"] B_desc = B_desc.lower() # 从PyTorch3D的坐标系转换到OpenCV的坐标系 A_pos = A_cloud.get_center() A_pos[0] = -A_pos[0]; A_pos[1] = -A_pos[1] B_pos = B_cloud.get_center() B_pos[0] = -B_pos[0]; B_pos[1] = -B_pos[1] A_rotation_matrix = A["rotation_matrix"] B_rotation_matrix = B["rotation_matrix"] B_rotation_matrix = A_rotation_matrix.T @ B_rotation_matrix # 在A的坐标系下,B的旋转矩阵 A_P_B = A_rotation_matrix.T @ (B_pos - A_pos) # 在A的坐标系下,B相对于A的位置 A_P_B_last = A['A_P_B'] theta1 = np.arctan2(A_P_B[2], A_P_B[0]) theta2 = np.arctan2(A_P_B_last[2], A_P_B_last[0]) theta1_upper = get_upper(theta1) if theta1_upper < np.pi and theta1_upper > -np.pi/2: theta1_lower = theta1_upper - np.pi / 2 position = True if theta1_upper > theta2 > theta1_lower else False else: # 135~180和-180~-135的情况 position = True if theta2 < -3/4*np.pi or theta2 > 3/4*np.pi else False max_angle = 30 angle_rad_A = np.arccos(np.clip(np.dot(A_rotation_matrix.T[0], np.array([-1,0,0])), -1.0, 1.0)) direction = angle_rad_A < max_angle / 180 * np.pi check = position and direction question_template = f"Are [A] and [B] maintaining their original relative relationship when viewed from the left of [A]?" question = question_template.replace("[A]", A_desc).replace("[B]", B_desc) answer = "Yes" if check else "No" score = 0 if check: score = 1 else: if position: w1 = 1 else: if theta1_upper < np.pi and theta1_upper > -np.pi/2: w1 = 1 - np.min([np.abs(theta1_upper-theta2), np.abs(theta2-theta1_lower)]) / (np.pi / 6) # 30度的阈值 else: # 135~180和-180~-135的情况 theta2 = theta2 + 2 * np.pi if theta2 < -3/4*np.pi else theta2 # 转化到0~2pi w1 = 1 - np.min([np.abs(1.25*np.pi-theta2), np.abs(theta2-0.75*np.pi)]) / (np.pi / 6) # 30度的阈值 if direction: w2 = 1 else: w2 = 1 - np.abs(angle_rad_A - max_angle / 180 * np.pi) / (np.pi / 6) # 30度的阈值 score = 0 if w1<0 or w2<0 else w1 * w2 return question, answer, check, score def CR_two_right(A, B): A_desc, A_cloud = A["caption"], A["pcd"] A_desc = A_desc.lower() B_desc, B_cloud = B["caption"], B["pcd"] B_desc = B_desc.lower() # 从PyTorch3D的坐标系转换到OpenCV的坐标系 A_pos = A_cloud.get_center() A_pos[0] = -A_pos[0]; A_pos[1] = -A_pos[1] B_pos = B_cloud.get_center() B_pos[0] = -B_pos[0]; B_pos[1] = -B_pos[1] A_rotation_matrix = A["rotation_matrix"] B_rotation_matrix = B["rotation_matrix"] B_rotation_matrix = A_rotation_matrix.T @ B_rotation_matrix # 在A的坐标系下,B的旋转矩阵 A_P_B = A_rotation_matrix.T @ (B_pos - A_pos) # 在A的坐标系下,B相对于A的位置 A_P_B_last = A['A_P_B'] theta1 = np.arctan2(A_P_B[2], A_P_B[0]) theta2 = np.arctan2(A_P_B_last[2], A_P_B_last[0]) theta1_upper = get_upper(theta1) if theta1_upper < np.pi and theta1_upper > -np.pi/2: theta1_lower = theta1_upper - np.pi / 2 position = True if theta1_upper > theta2 > theta1_lower else False else: # 135~180和-180~-135的情况 position = True if theta2 < -3/4*np.pi or theta2 > 3/4*np.pi else False max_angle = 30 # angle_rad_AB = np.arccos(np.clip(np.dot(B_rotation_matrix.T[0], np.array([1,0,0])), -1.0, 1.0)) # same_direction = angle_rad_AB < max_angle / 180 * np.pi angle_rad_A = np.arccos(np.clip(np.dot(A_rotation_matrix.T[0], np.array([1,0,0])), -1.0, 1.0)) direction = angle_rad_A < max_angle / 180 * np.pi check = position and direction question_template = f"Are [A] and [B] maintaining their original relative relationship when viewed from the right of [A]?" question = question_template.replace("[A]", A_desc).replace("[B]", B_desc) answer = "Yes" if check else "No" score = 0 if check: score = 1 else: if position: w1 = 1 else: if theta1_upper < np.pi and theta1_upper > -np.pi/2: w1 = 1 - np.min([np.abs(theta1_upper-theta2), np.abs(theta2-theta1_lower)]) / (np.pi / 6) # 30度的阈值 else: # 135~180和-180~-135的情况 theta2 = theta2 + 2 * np.pi if theta2 < -3/4*np.pi else theta2 # 转化到0~2pi w1 = 1 - np.min([np.abs(1.25*np.pi-theta2), np.abs(theta2-0.75*np.pi)]) / (np.pi / 6) # 30度的阈值 if direction: w2 = 1 else: w2 = 1 - np.abs(angle_rad_A - max_angle / 180 * np.pi) / (np.pi / 6) # 30度的阈值 score = 0 if w1<0 or w2<0 else w1 * w2 return question, answer, check, score def CR_three_front(A, B, C): A_desc, A_cloud = A["caption"], A["pcd"] A_desc = A_desc.lower() B_desc, B_cloud = B["caption"], B["pcd"] B_desc = B_desc.lower() C_desc, C_cloud = C["caption"], C["pcd"] C_desc = C_desc.lower() # 从PyTorch3D的坐标系转换到OpenCV的坐标系 A_pos = A_cloud.get_center() A_pos[0] = -A_pos[0]; A_pos[1] = -A_pos[1] B_pos = B_cloud.get_center() B_pos[0] = -B_pos[0]; B_pos[1] = -B_pos[1] C_pos = C_cloud.get_center() C_pos[0] = -C_pos[0]; C_pos[1] = -C_pos[1] A_rotation_matrix = A["rotation_matrix"] B_rotation_matrix = B["rotation_matrix"] C_rotation_matrix = C["rotation_matrix"] A_rotation_matrix = C_rotation_matrix.T @ A_rotation_matrix # 在C的坐标系下,A的旋转矩阵 B_rotation_matrix = C_rotation_matrix.T @ B_rotation_matrix # 在C的坐标系下,B的旋转矩阵 C_P_A = C_rotation_matrix.T @ (A_pos - C_pos) # 在C的坐标系下,A相对于C的位置 C_P_B = C_rotation_matrix.T @ (B_pos - C_pos) # 在C的坐标系下,B相对于C的位置 C_P_A_last = C['C_P_A'] C_P_B_last = C['C_P_B'] theta_CA1 = np.arctan2(C_P_A[2], C_P_A[0]) theta_CB1 = np.arctan2(C_P_B[2], C_P_B[0]) theta_CA2 = np.arctan2(C_P_A_last[2], C_P_A_last[0]) theta_CB2 = np.arctan2(C_P_B_last[2], C_P_B_last[0]) theta_CA1_upper = get_upper(theta_CA1) theta_CA1_lower = theta_CA1_upper - np.pi / 2 if theta_CA1_upper < np.pi and theta_CA1_upper > -np.pi/2: theta1_lower = theta_CA1_upper - np.pi / 2 position_CA = True if theta_CA1_upper > theta_CA2 > theta1_lower else False else: # 135~180和-180~-135的情况 position_CA = True if theta_CA2 < -3/4*np.pi or theta_CA2 > 3/4*np.pi else False theta_CB1_upper = get_upper(theta_CB1) theta_CB1_lower = theta_CB1_upper - np.pi / 2 if theta_CB1_upper < np.pi and theta_CB1_upper > -np.pi/2: theta1_lower = theta_CB1_upper - np.pi / 2 position_CB = True if theta_CB1_upper > theta_CB2 > theta1_lower else False else: # 135~180和-180~-135的情况 position_CB = True if theta_CB2 < -3/4*np.pi or theta_CB2 > 3/4*np.pi else False position = position_CA and position_CB max_angle = 30 angle_rad_C = np.arccos(np.clip(np.dot(C_rotation_matrix.T[0], np.array([0,0,-1])), -1.0, 1.0)) direction = angle_rad_C < max_angle / 180 * np.pi check = position and direction question_template = f"Are [A], [B] and [C] maintaining their original relative relationship when viewed from the front of [C]?" question = question_template.replace("[A]", A_desc).replace("[B]", B_desc).replace("[C]", C_desc) answer = "Yes" if check else "No" score = 0 if check: score = 1 else: if position_CA: w1 = 1 else: if theta_CA1_upper < np.pi and theta_CA1_upper > -np.pi/2: w1 = 1 - np.min([np.abs(theta_CA1_upper-theta_CA2), np.abs(theta_CA2-theta_CA1_lower)]) / (np.pi / 6) # 30度的阈值 else: # 135~180和-180~-135的情况 theta_CA2 = theta_CA2 + 2 * np.pi if theta_CA2 < -3/4*np.pi else theta_CA2 w1 = 1 - np.min([np.abs(1.25*np.pi-theta_CA2), np.abs(theta_CA2-0.75*np.pi)]) / (np.pi / 6) # 30度的阈值 if position_CB: w2 = 1 else: if theta_CB1_upper < np.pi and theta_CB1_upper > -np.pi/2: w2 = 1 - np.min([np.abs(theta_CB1_upper-theta_CB2), np.abs(theta_CB2-theta_CB1_lower)]) / (np.pi / 6) else: # 135~180和-180~-135的情况 theta_CB2 = theta_CB2 + 2 * np.pi if theta_CB2 < -3/4*np.pi else theta_CB2 w2 = 1 - np.min([np.abs(1.25*np.pi-theta_CB2), np.abs(theta_CB2-0.75*np.pi)]) / (np.pi / 6) # 30度的阈值 if direction: w3 = 1 else: w3 = 1 - np.abs(angle_rad_C - max_angle / 180 * np.pi) / (np.pi / 6) # 30度的阈值 score = 0 if w1<0 or w2<0 or w3<0 else w1 * w2 * w3 return question, answer, check, score def CR_three_back(A, B, C): A_desc, A_cloud = A["caption"], A["pcd"] A_desc = A_desc.lower() B_desc, B_cloud = B["caption"], B["pcd"] B_desc = B_desc.lower() C_desc, C_cloud = C["caption"], C["pcd"] C_desc = C_desc.lower() # 从PyTorch3D的坐标系转换到OpenCV的坐标系 A_pos = A_cloud.get_center() A_pos[0] = -A_pos[0]; A_pos[1] = -A_pos[1] B_pos = B_cloud.get_center() B_pos[0] = -B_pos[0]; B_pos[1] = -B_pos[1] C_pos = C_cloud.get_center() C_pos[0] = -C_pos[0]; C_pos[1] = -C_pos[1] A_rotation_matrix = A["rotation_matrix"] B_rotation_matrix = B["rotation_matrix"] C_rotation_matrix = C["rotation_matrix"] A_rotation_matrix = C_rotation_matrix.T @ A_rotation_matrix # 在C的坐标系下,A的旋转矩阵 B_rotation_matrix = C_rotation_matrix.T @ B_rotation_matrix # 在C的坐标系下,B的旋转矩阵 C_P_A = C_rotation_matrix.T @ (A_pos - C_pos) # 在C的坐标系下,A相对于C的位置 C_P_B = C_rotation_matrix.T @ (B_pos - C_pos) # 在C的坐标系下,B相对于C的位置 C_P_A_last = C['C_P_A'] C_P_B_last = C['C_P_B'] theta_CA1 = np.arctan2(C_P_A[2], C_P_A[0]) theta_CB1 = np.arctan2(C_P_B[2], C_P_B[0]) theta_CA2 = np.arctan2(C_P_A_last[2], C_P_A_last[0]) theta_CB2 = np.arctan2(C_P_B_last[2], C_P_B_last[0]) theta_CA1_upper = get_upper(theta_CA1) theta_CA1_lower = theta_CA1_upper - np.pi / 2 if theta_CA1_upper < np.pi and theta_CA1_upper > -np.pi/2: theta1_lower = theta_CA1_upper - np.pi / 2 position_CA = True if theta_CA1_upper > theta_CA2 > theta1_lower else False else: # 135~180和-180~-135的情况 position_CA = True if theta_CA2 < -3/4*np.pi or theta_CA2 > 3/4*np.pi else False theta_CB1_upper = get_upper(theta_CB1) theta_CB1_lower = theta_CB1_upper - np.pi / 2 if theta_CB1_upper < np.pi and theta_CB1_upper > -np.pi/2: theta1_lower = theta_CB1_upper - np.pi / 2 position_CB = True if theta_CB1_upper > theta_CB2 > theta1_lower else False else: # 135~180和-180~-135的情况 position_CB = True if theta_CB2 < -3/4*np.pi or theta_CB2 > 3/4*np.pi else False position = position_CA and position_CB max_angle = 30 # angle_rad_AC = np.arccos(np.clip(np.dot(A_rotation_matrix.T[0], np.array([1,0,0])), -1.0, 1.0)) # angle_rad_BC = np.arccos(np.clip(np.dot(B_rotation_matrix.T[0], np.array([1,0,0])), -1.0, 1.0)) # same_direction_AC = angle_rad_AC < max_angle / 180 * np.pi # same_direction_BC = angle_rad_BC < max_angle / 180 * np.pi # same_direction = same_direction_AC and same_direction_BC angle_rad_C = np.arccos(np.clip(np.dot(C_rotation_matrix.T[0], np.array([0,0,1])), -1.0, 1.0)) direction = angle_rad_C < max_angle / 180 * np.pi check = position and direction question_template = f"Are [A], [B] and [C] maintaining their original relative relationship when viewed from the back of [C]?" question = question_template.replace("[A]", A_desc).replace("[B]", B_desc).replace("[C]", C_desc) answer = "Yes" if check else "No" score = 0 if check: score = 1 else: if position_CA: w1 = 1 else: if theta_CA1_upper < np.pi and theta_CA1_upper > -np.pi/2: w1 = 1 - np.min([np.abs(theta_CA1_upper-theta_CA2), np.abs(theta_CA2-theta_CA1_lower)]) / (np.pi / 6) # 30度的阈值 else: # 135~180和-180~-135的情况 theta_CA2 = theta_CA2 + 2 * np.pi if theta_CA2 < -3/4*np.pi else theta_CA2 w1 = 1 - np.min([np.abs(1.25*np.pi-theta_CA2), np.abs(theta_CA2-0.75*np.pi)]) / (np.pi / 6) # 30度的阈值 if position_CB: w2 = 1 else: if theta_CB1_upper < np.pi and theta_CB1_upper > -np.pi/2: w2 = 1 - np.min([np.abs(theta_CB1_upper-theta_CB2), np.abs(theta_CB2-theta_CB1_lower)]) / (np.pi / 6) else: # 135~180和-180~-135的情况 theta_CB2 = theta_CB2 + 2 * np.pi if theta_CB2 < -3/4*np.pi else theta_CB2 w2 = 1 - np.min([np.abs(1.25*np.pi-theta_CB2), np.abs(theta_CB2-0.75*np.pi)]) / (np.pi / 6) # 30度的阈值 if direction: w3 = 1 else: w3 = 1 - np.abs(angle_rad_C - max_angle / 180 * np.pi) / (np.pi / 6) # 30度的阈值 score = 0 if w1<0 or w2<0 or w3<0 else w1 * w2 * w3 return question, answer, check, score def CR_three_left(A, B, C): A_desc, A_cloud = A["caption"], A["pcd"] A_desc = A_desc.lower() B_desc, B_cloud = B["caption"], B["pcd"] B_desc = B_desc.lower() C_desc, C_cloud = C["caption"], C["pcd"] C_desc = C_desc.lower() # 从PyTorch3D的坐标系转换到OpenCV的坐标系 A_pos = A_cloud.get_center() A_pos[0] = -A_pos[0]; A_pos[1] = -A_pos[1] B_pos = B_cloud.get_center() B_pos[0] = -B_pos[0]; B_pos[1] = -B_pos[1] C_pos = C_cloud.get_center() C_pos[0] = -C_pos[0]; C_pos[1] = -C_pos[1] A_rotation_matrix = A["rotation_matrix"] B_rotation_matrix = B["rotation_matrix"] C_rotation_matrix = C["rotation_matrix"] A_rotation_matrix = C_rotation_matrix.T @ A_rotation_matrix # 在C的坐标系下,A的旋转矩阵 B_rotation_matrix = C_rotation_matrix.T @ B_rotation_matrix # 在C的坐标系下,B的旋转矩阵 C_P_A = C_rotation_matrix.T @ (A_pos - C_pos) # 在C的坐标系下,A相对于C的位置 C_P_B = C_rotation_matrix.T @ (B_pos - C_pos) # 在C的坐标系下,B相对于C的位置 C_P_A_last = C['C_P_A'] C_P_B_last = C['C_P_B'] theta_CA1 = np.arctan2(C_P_A[2], C_P_A[0]) theta_CB1 = np.arctan2(C_P_B[2], C_P_B[0]) theta_CA2 = np.arctan2(C_P_A_last[2], C_P_A_last[0]) theta_CB2 = np.arctan2(C_P_B_last[2], C_P_B_last[0]) theta_CA1_upper = get_upper(theta_CA1) theta_CA1_lower = theta_CA1_upper - np.pi / 2 if theta_CA1_upper < np.pi and theta_CA1_upper > -np.pi/2: theta1_lower = theta_CA1_upper - np.pi / 2 position_CA = True if theta_CA1_upper > theta_CA2 > theta1_lower else False else: # 135~180和-180~-135的情况 position_CA = True if theta_CA2 < -3/4*np.pi or theta_CA2 > 3/4*np.pi else False theta_CB1_upper = get_upper(theta_CB1) theta_CB1_lower = theta_CB1_upper - np.pi / 2 if theta_CB1_upper < np.pi and theta_CB1_upper > -np.pi/2: theta1_lower = theta_CB1_upper - np.pi / 2 position_CB = True if theta_CB1_upper > theta_CB2 > theta1_lower else False else: # 135~180和-180~-135的情况 position_CB = True if theta_CB2 < -3/4*np.pi or theta_CB2 > 3/4*np.pi else False position = position_CA and position_CB max_angle = 30 # angle_rad_AC = np.arccos(np.clip(np.dot(A_rotation_matrix.T[0], np.array([1,0,0])), -1.0, 1.0)) # angle_rad_BC = np.arccos(np.clip(np.dot(B_rotation_matrix.T[0], np.array([1,0,0])), -1.0, 1.0)) # same_direction_AC = angle_rad_AC < max_angle / 180 * np.pi # same_direction_BC = angle_rad_BC < max_angle / 180 * np.pi # same_direction = same_direction_AC and same_direction_BC angle_rad_C = np.arccos(np.clip(np.dot(C_rotation_matrix.T[0], np.array([-1,0,0])), -1.0, 1.0)) direction = angle_rad_C < max_angle / 180 * np.pi check = position and direction question_template = f"Are [A], [B] and [C] maintaining their original relative relationship when viewed from the left of [C]?" question = question_template.replace("[A]", A_desc).replace("[B]", B_desc).replace("[C]", C_desc) answer = "Yes" if check else "No" score = 0 if check: score = 1 else: if position_CA: w1 = 1 else: if theta_CA1_upper < np.pi and theta_CA1_upper > -np.pi/2: w1 = 1 - np.min([np.abs(theta_CA1_upper-theta_CA2), np.abs(theta_CA2-theta_CA1_lower)]) / (np.pi / 6) # 30度的阈值 else: # 135~180和-180~-135的情况 theta_CA2 = theta_CA2 + 2 * np.pi if theta_CA2 < -3/4*np.pi else theta_CA2 w1 = 1 - np.min([np.abs(1.25*np.pi-theta_CA2), np.abs(theta_CA2-0.75*np.pi)]) / (np.pi / 6) # 30度的阈值 if position_CB: w2 = 1 else: if theta_CB1_upper < np.pi and theta_CB1_upper > -np.pi/2: w2 = 1 - np.min([np.abs(theta_CB1_upper-theta_CB2), np.abs(theta_CB2-theta_CB1_lower)]) / (np.pi / 6) else: # 135~180和-180~-135的情况 theta_CB2 = theta_CB2 + 2 * np.pi if theta_CB2 < -3/4*np.pi else theta_CB2 w2 = 1 - np.min([np.abs(1.25*np.pi-theta_CB2), np.abs(theta_CB2-0.75*np.pi)]) / (np.pi / 6) # 30度的阈值 if direction: w3 = 1 else: w3 = 1 - np.abs(angle_rad_C - max_angle / 180 * np.pi) / (np.pi / 6) # 30度的阈值 score = 0 if w1<0 or w2<0 or w3<0 else w1 * w2 * w3 return question, answer, check, score def CR_three_right(A, B, C): A_desc, A_cloud = A["caption"], A["pcd"] A_desc = A_desc.lower() B_desc, B_cloud = B["caption"], B["pcd"] B_desc = B_desc.lower() C_desc, C_cloud = C["caption"], C["pcd"] C_desc = C_desc.lower() # 从PyTorch3D的坐标系转换到OpenCV的坐标系 A_pos = A_cloud.get_center() A_pos[0] = -A_pos[0]; A_pos[1] = -A_pos[1] B_pos = B_cloud.get_center() B_pos[0] = -B_pos[0]; B_pos[1] = -B_pos[1] C_pos = C_cloud.get_center() C_pos[0] = -C_pos[0]; C_pos[1] = -C_pos[1] A_rotation_matrix = A["rotation_matrix"] B_rotation_matrix = B["rotation_matrix"] C_rotation_matrix = C["rotation_matrix"] A_rotation_matrix = C_rotation_matrix.T @ A_rotation_matrix # 在C的坐标系下,A的旋转矩阵 B_rotation_matrix = C_rotation_matrix.T @ B_rotation_matrix # 在C的坐标系下,B的旋转矩阵 C_P_A = C_rotation_matrix.T @ (A_pos - C_pos) # 在C的坐标系下,A相对于C的位置 C_P_B = C_rotation_matrix.T @ (B_pos - C_pos) # 在C的坐标系下,B相对于C的位置 C_P_A_last = C['C_P_A'] C_P_B_last = C['C_P_B'] theta_CA1 = np.arctan2(C_P_A[2], C_P_A[0]) theta_CB1 = np.arctan2(C_P_B[2], C_P_B[0]) theta_CA2 = np.arctan2(C_P_A_last[2], C_P_A_last[0]) theta_CB2 = np.arctan2(C_P_B_last[2], C_P_B_last[0]) theta_CA1_upper = get_upper(theta_CA1) theta_CA1_lower = theta_CA1_upper - np.pi / 2 if theta_CA1_upper < np.pi and theta_CA1_upper > -np.pi/2: theta1_lower = theta_CA1_upper - np.pi / 2 position_CA = True if theta_CA1_upper > theta_CA2 > theta1_lower else False else: # 135~180和-180~-135的情况 position_CA = True if theta_CA2 < -3/4*np.pi or theta_CA2 > 3/4*np.pi else False theta_CB1_upper = get_upper(theta_CB1) theta_CB1_lower = theta_CB1_upper - np.pi / 2 if theta_CB1_upper < np.pi and theta_CB1_upper > -np.pi/2: theta1_lower = theta_CB1_upper - np.pi / 2 position_CB = True if theta_CB1_upper > theta_CB2 > theta1_lower else False else: # 135~180和-180~-135的情况 position_CB = True if theta_CB2 < -3/4*np.pi or theta_CB2 > 3/4*np.pi else False position = position_CA and position_CB max_angle = 30 # angle_rad_AC = np.arccos(np.clip(np.dot(A_rotation_matrix.T[0], np.array([1,0,0])), -1.0, 1.0)) # angle_rad_BC = np.arccos(np.clip(np.dot(B_rotation_matrix.T[0], np.array([1,0,0])), -1.0, 1.0)) # same_direction_AC = angle_rad_AC < max_angle / 180 * np.pi # same_direction_BC = angle_rad_BC < max_angle / 180 * np.pi # same_direction = same_direction_AC and same_direction_BC angle_rad_C = np.arccos(np.clip(np.dot(C_rotation_matrix.T[0], np.array([1,0,0])), -1.0, 1.0)) direction = angle_rad_C < max_angle / 180 * np.pi check = position and direction question_template = f"Are [A], [B] and [C] maintaining their original relative relationship when viewed from the right of [C]?" question = question_template.replace("[A]", A_desc).replace("[B]", B_desc).replace("[C]", C_desc) answer = "Yes" if check else "No" score = 0 if check: score = 1 else: if position_CA: w1 = 1 else: if theta_CA1_upper < np.pi and theta_CA1_upper > -np.pi/2: w1 = 1 - np.min([np.abs(theta_CA1_upper-theta_CA2), np.abs(theta_CA2-theta_CA1_lower)]) / (np.pi / 6) # 30度的阈值 else: # 135~180和-180~-135的情况 theta_CA2 = theta_CA2 + 2 * np.pi if theta_CA2 < -3/4*np.pi else theta_CA2 w1 = 1 - np.min([np.abs(1.25*np.pi-theta_CA2), np.abs(theta_CA2-0.75*np.pi)]) / (np.pi / 6) # 30度的阈值 if position_CB: w2 = 1 else: if theta_CB1_upper < np.pi and theta_CB1_upper > -np.pi/2: w2 = 1 - np.min([np.abs(theta_CB1_upper-theta_CB2), np.abs(theta_CB2-theta_CB1_lower)]) / (np.pi / 6) else: # 135~180和-180~-135的情况 theta_CB2 = theta_CB2 + 2 * np.pi if theta_CB2 < -3/4*np.pi else theta_CB2 w2 = 1 - np.min([np.abs(1.25*np.pi-theta_CB2), np.abs(theta_CB2-0.75*np.pi)]) / (np.pi / 6) # 30度的阈值 if direction: w3 = 1 else: w3 = 1 - np.abs(angle_rad_C - max_angle / 180 * np.pi) / (np.pi / 6) # 30度的阈值 score = 0 if w1<0 or w2<0 or w3<0 else w1 * w2 * w3 return question, answer, check, score