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ArgoverseDataset.py
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ArgoverseDataset.py
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''' ArgoverseForecastDataset继承了torch.utils.data.Dataset,实现三个函数用于初始化和获取地图数据
加载Argoverse HD map 和 Forecast 数据集,并将地图和轨迹数据进行向量化(vector map)归一化等处理
由__getitem__函数将处理过的数据转为tensor并返回 '''
import torch
import torch.utils.data
import torchvision.transforms as T
import numpy as np
import argoverse
from argoverse.map_representation.map_api import ArgoverseMap
from argoverse.data_loading.argoverse_tracking_loader import ArgoverseTrackingLoader
from argoverse.data_loading.argoverse_forecasting_loader import ArgoverseForecastingLoader
from tqdm import tqdm
import matplotlib.pyplot as plt
from common import *
import json
import pickle
import sys
## 根据轨迹点p0(x0,y0), p1(x1,y1)计算它们组成的向量的2x2旋转矩阵
def get_rotate_matrix(trajectory):
x0, y0, x1, y1 = trajectory.flatten()
vec1 = np.array([x1 - x0, y1 - y0])
vec2 = np.array([0, 1])
cosalpha = vec1.dot(vec2) / (np.sqrt(vec1.dot(vec1)) * 1 + 1e-5)
sinalpha = np.sqrt(1 - cosalpha * cosalpha)
if x1 - x0 < 0:
sinalpha = -sinalpha
rotate_matrix = np.array([[cosalpha, -sinalpha], [sinalpha, cosalpha]])
return rotate_matrix
class ArgoverseForecastDataset(torch.utils.data.Dataset):
def __init__(self, cfg):
super().__init__()
self.am = ArgoverseMap() # HD map in argoverse-api/map_files
self.axis_range = self.get_map_range(self.am) # 获取整个城市的坐标范围,用于归一化坐标
self.city_halluc_bbox_table, self.city_halluc_tableidx_to_laneid_map = self.am.build_hallucinated_lane_bbox_index() # 用于快速查询车道
self.laneid_map = self.process_laneid_map() # {'PIT': {9604854: '0'}, 'MIA': {9605252: '0'}}
self.vector_map, self.extra_map = self.generate_vector_map() # get HD map and convert to vector, extra_map includes OBJECT_TYP, turn_direction, lane_id, in_intersection, has_traffic_control
# am.draw_lane(city_halluc_tableidx_to_laneid_map['PIT']['494'], 'PIT')
# self.save_vector_map(self.vector_map)
self.last_observe = cfg['last_observe']
##set root_dir to the correct path to your dataset folder
self.root_dir = cfg['data_locate']
self.device = cfg['device']
self.afl = ArgoverseForecastingLoader(self.root_dir)
# self.map_feature = dict(PIT=[], MIA=[])
self.city_name, self.center_xy, self.rotate_matrix = dict(), dict(), dict()
def __len__(self):
return len(self.afl)
def __getitem__(self, index): # 迭代获取数据函数,在该函数中读取了trajectory数据,同时对坐标进行了一系列预处理,最后转换为归一化的轨迹和地图tensor
# self.am.find_local_lane_polygons()
self.trajectory, city_name, extra_fields = self.get_trajectory(index) # 由索引获取一段轨迹,见图2021-10-11 21-36-01 的屏幕截图.png
traj_id = extra_fields['trajectory_id'][0] # 将xxx.csv中文件名作为scenario id,数据见data.txt,由于是同一段轨迹,所以id是一样的,所以我们取第0个
self.city_name.update({str(traj_id): city_name})
center_xy = self.trajectory[self.last_observe-1][1] # 将第last_observe-1个轨迹点作为中心点
self.center_xy.update({str(traj_id): center_xy}) # 选取一个中心点,用于归一化处理,数据见data.txt, {'425': array([ 186.48895452, 1560.94612336])}
trajectory_feature = (self.trajectory - np.array(center_xy).reshape(1, 1, 2)).reshape(-1, 4) # [[x1,y1,x2,y2],[x3,y3,x4,y4],...]
rotate_matrix = get_rotate_matrix(trajectory_feature[self.last_observe, :]) # get rotate coordinate from last_observe vector
self.rotate_matrix.update({str(traj_id): rotate_matrix})
# 如果所有轨迹点都在一条直线上,那么旋转后的点都在y轴上
trajectory_feature = ((trajectory_feature.reshape(-1, 2)).dot(rotate_matrix.T)).reshape(-1, 4) # 轨迹特征旋转并reshape
# print('trajectory_feature before normalize :')
# print(trajectory_feature)
trajectory_feature = self.normalize_coordinate(trajectory_feature, city_name) #
# np.savetxt('traj.txt',trajectory_feature,fmt='%0.8f')
# 轨迹特征为6维[x1,y1,x2,y2,TIMESTAMP,trajectory_id]
# self.traj_feature = torch.from_numpy(np.hstack((trajectory_feature,
# extra_fields['TIMESTAMP'].reshape(-1, 1),
# # extra_fields['OBJECT_TYPE'].reshape(-1, 1),
# extra_fields['trajectory_id'].reshape(-1, 1)))).float()
self.traj_feature = torch.from_numpy(trajectory_feature).float()
# map_feature_dict = dict(PIT=[], MIA=[])
# 地图特征为8维[v0x,v0y,v1x,v1y,turn_direction,in_intersection,has_traffic_control,lane_id]
# 上面得到了self.center_xy和self.rotate_matrix,下面对每个点地图也需要做相应的去中心化和旋转
self.map_feature = []
# mf = []
lane_ids = self.am.get_lane_ids_in_xy_bbox(center_xy[0], center_xy[1], city_name, 20)
for id in lane_ids:
index_str = self.laneid_map[city_name][id]
i = int(index_str)
vecmap_feature = (self.vector_map[city_name][i] - np.array(center_xy).reshape(1, 1, 2)).reshape(-1, 2) # 地图点去中心点
vecmap_feature = (vecmap_feature.dot(rotate_matrix.T)).reshape(-1, 4) # 旋转并reshape
vecmap_feature = self.normalize_coordinate(vecmap_feature, city_name) # 再归一化
# mf.append(vecmap_feature)
tmp_tensor = torch.from_numpy(np.hstack((vecmap_feature,
self.extra_map[city_name]['turn_direction'][i],
self.extra_map[city_name]['in_intersection'][i],
self.extra_map[city_name]['has_traffic_control'][i],
# self.extra_map[city_name]['OBJECT_TYPE'][i],
self.extra_map[city_name]['lane_id'][i])))
self.map_feature.append(tmp_tensor)
# map_length = len(self.map_feature)
# if map_length > 32:
# self.map_feature = self.map_feature[:32]
# elif map_length < 32:
# need_align = True
# while need_align:
# for i in range(map_length):
# self.map_feature.append(self.map_feature[i])
# if len(self.map_feature) == 32:
# need_align = False
# break
# for city in ['PIT', 'MIA']:
# for i in range(len(self.vector_map[city])):
# map_feature = (self.vector_map[city][i] - np.array(center_xy).reshape(1, 1, 2)).reshape(-1, 2) # 地图点减去中心点作为map_feature
# map_feature = (map_feature.dot(rotate_matrix.T)).reshape(-1, 4) # 地图特征旋转并reshape
# map_feature = self.normalize_coordinate(map_feature, city)
# tmp_tensor = torch.from_numpy(np.hstack((map_feature,
# self.extra_map[city]['turn_direction'][i],
# self.extra_map[city]['in_intersection'][i],
# self.extra_map[city]['has_traffic_control'][i],
# # self.extra_map[city]['OBJECT_TYPE'][i],
# self.extra_map[city]['lane_id'][i])))
# map_feature_dict[city].append(tmp_tensor.float())
# # self.map_feature[city] = np.array(self.map_feature[city])
# self.map_feature[city] = map_feature_dict[city]
# self.map_feature['city_name'] = city_name
# mapfeature = np.vstack(mf)
# np.savetxt('map.txt',mapfeature,fmt='%0.8f')
# sys.exit()
return self.traj_feature, self.map_feature # 返回的是一条5s轨迹向量(49,6)和中心点周围的n个地图向量(n,18,8)
def get_trajectory(self, index):
seq_path = self.afl.seq_list[index]
data = self.afl.get(seq_path).seq_df # Get the dataframe for the current sequence. 见docs/data.txt
data = data[data['OBJECT_TYPE'] == 'AGENT'] # will get AGENT traject, 取出所有agent的轨迹
extra_fields = dict(TIMESTAMP=[], OBJECT_TYPE=[], trajectory_id=[])
polyline = []
j = int(str(seq_path).split('/')[-1].split('.')[0]) # forecating sequence 123.cvs文件名去掉后缀(一串数字)
flag = True
city_name = ''
for _, row in data.iterrows():
if flag:
xlast = row['X']
ylast = row['Y']
tlast = row['TIMESTAMP']
city_name = row['CITY_NAME']
flag = False
continue
startpoint = np.array([xlast, ylast]) # 相邻点组成向量
endpoint = np.array([row['X'], row['Y']])
# plt.annotate('', xy=(endpoint[0],endpoint[1]),xytext=(startpoint[0],startpoint[1]),arrowprops=dict(arrowstyle="->",connectionstyle="arc3"))
xlast = row['X']
ylast = row['Y']
extra_fields['TIMESTAMP'].append(tlast)
extra_fields['OBJECT_TYPE'].append(0) # 'AGENT'
extra_fields['trajectory_id'].append(j) # 'AGENT'
tlast = row['TIMESTAMP']
polyline.append([startpoint, endpoint])
extra_fields['TIMESTAMP'] = np.array(extra_fields['TIMESTAMP'])
extra_fields['TIMESTAMP'] -= np.min(extra_fields['TIMESTAMP']) # adjust time stamp
extra_fields['OBJECT_TYPE'] = np.array(extra_fields['OBJECT_TYPE'])
extra_fields['trajectory_id'] = np.array(extra_fields['trajectory_id'])
# plt.show()
return np.array(polyline), city_name, extra_fields
def generate_vector_map(self): # 读取HD map并转换成vector,返回vector map和由其他信息组成的extra_map
vector_map = {'PIT': [], 'MIA': []}
extra_map = {'PIT': dict(OBJECT_TYPE=[], turn_direction=[], lane_id=[], in_intersection=[],
has_traffic_control=[]),
'MIA': dict(OBJECT_TYPE=[], turn_direction=[], lane_id=[], in_intersection=[],
has_traffic_control=[])}
polyline = []
# index = 1
pbar = tqdm(total=17326) # 进度条
pbar.set_description("Generating Vector Map")
# city_name = 'MIA'
# for i in range(1):
# key = 9624155 + i
# pts = self.am.get_lane_segment_polygon(key, city_name)
# pts = pts[:,:2]
# print(pts)
# x1 = pts[:,0]
# y1 = pts[:,1]
# plt.plot(x1, y1,'ro')
# pts_len = pts.shape[0] // 2 # 21 // 2 返回10
# positive_pts = pts[:pts_len, :2] # 车道左边界(x,y)坐标
# negative_pts = pts[pts_len:2 * pts_len, :2] # 右边界
# for i in range(pts_len - 1):
# v1 = np.array([positive_pts[i], positive_pts[i + 1]]) # 车道左边界向量
# v2 = np.array([negative_pts[pts_len - 1 - i], negative_pts[pts_len - i - 2]]) # 右边界向量
# plt.annotate('', xy=(positive_pts[i+1][0],positive_pts[i+1][1]),xytext=(positive_pts[i][0],positive_pts[i][1]),arrowprops=dict(arrowstyle="->",connectionstyle="arc3"))
# plt.annotate('', xy=(negative_pts[pts_len - i - 2][0],negative_pts[pts_len - i - 2][1]),xytext=(negative_pts[pts_len - 1 - i][0],negative_pts[pts_len - 1 - i][1]),arrowprops=dict(arrowstyle="->",connectionstyle="arc3"))
# plt.show()
for city_name in ['PIT', 'MIA']:
for key in self.laneid_map[city_name]: # lane id
# 由lane_id (key) 和 city_name 返回的pts是由21个三维坐标点(x,y,z)组成的一个闭合车道(第一个点和最后一个点重合)
pts = self.am.get_lane_segment_polygon(key, city_name) # get lane boundries sample points, stitch them as vector (specified in the paper)
turn_str = self.am.get_lane_turn_direction(key, city_name)
if turn_str == 'LEFT':
turn = -1
elif turn_str == 'RIGHT':
turn = 1
else:
turn = 0
pts_len = pts.shape[0] // 2 # 21 // 2 返回10
positive_pts = pts[:pts_len, :2] # 车道左边界(x,y)坐标
negative_pts = pts[pts_len:2 * pts_len, :2] # 右边界
# if city_name == 'PIT':
# plt.plot(pts[:pts_len, 0], pts[:pts_len, 1])
# plt.plot(pts[pts_len:2 * pts_len, 0], pts[pts_len:2 * pts_len, 1])
polyline.clear()
for i in range(pts_len - 1):
v1 = np.array([positive_pts[i], positive_pts[i + 1]]) # 车道左边界向量,二维向量只用xy坐标
v2 = np.array([negative_pts[pts_len - 1 - i], negative_pts[pts_len - i - 2]]) # 右边界向量
polyline.append(v1)
polyline.append(v2)
# extra_field['table_index'] = self.laneid_map[city_name][key]
repeat_t = 2*(pts_len-1)
# 最后得到的polyline是18维的,每一维是用两个点表示的向量,转成np.array再加到vector_map
vector_map[city_name].append(np.array(polyline).copy())
extra_map[city_name]['turn_direction'].append(np.repeat(turn, repeat_t, axis=0).reshape(-1, 1))
extra_map[city_name]['OBJECT_TYPE'].append(np.repeat(-1, repeat_t, axis=0).reshape(-1, 1)) #HD Map
extra_map[city_name]['lane_id'].append(np.repeat(int(key), repeat_t, axis=0).reshape(-1, 1))
extra_map[city_name]['in_intersection'].append(np.repeat(
1 * self.am.lane_is_in_intersection(key, city_name), repeat_t, axis=0).reshape(-1, 1))
extra_map[city_name]['has_traffic_control'].append(np.repeat(
1 * self.am.lane_has_traffic_control_measure(key, city_name), repeat_t, axis=0).reshape(-1, 1))
# if index > 10:
# break
# index = index + 1
pbar.update(1)
pbar.close()
# plt.show()
# mylog = open('extra_map.txt', mode = 'a',encoding='utf-8')
# print(extra_map, file=mylog)
print("Generate Vector Map Successfully!")
return vector_map, extra_map #vector_map:list
def process_laneid_map(self):
laneid_map = {}
tmp_map = {}
tmp1_map = {}
for key in self.city_halluc_tableidx_to_laneid_map['PIT']:
tmp_map[self.city_halluc_tableidx_to_laneid_map['PIT'][key]] = key
laneid_map['PIT'] = tmp_map
for key in self.city_halluc_tableidx_to_laneid_map['MIA']:
tmp1_map[self.city_halluc_tableidx_to_laneid_map['MIA'][key]] = key
laneid_map['MIA'] = tmp1_map
return laneid_map
def get_map_range(self, am):
map_range = dict(PIT={}, MIA={})
for city_name in ['PIT', 'MIA']: # 匹兹堡,迈阿密
poly = am.get_vector_map_lane_polygons(city_name) # Get list of lane polygons for a specified city
poly_modified = (np.vstack(poly))[:, :2] # 所有地图数据垂直排列,取前两列xy
max_coordinate = np.max(poly_modified, axis=0) # xy轴的最大值和最小值
min_coordinate = np.min(poly_modified, axis=0)
map_range[city_name].update({'max': max_coordinate})
map_range[city_name].update({'min': min_coordinate})
print(city_name + ' map range :')
print(max_coordinate)
print(min_coordinate)
return map_range
def normalize_coordinate(self, array, city_name):
max_coordinate = self.axis_range[city_name]['max']
min_coordinate = self.axis_range[city_name]['min']
array = (100.*(array.reshape(-1, 2)) / (max_coordinate - min_coordinate)).reshape(-1,4)
return array
def save_vector_map(self, vector_map):
save_path = "./data/vector_map/"
for city_name in ['PIT', 'MIA']:
tmp_map = np.vstack(vector_map[city_name]).reshape(-1, 4)
np.save(save_path+city_name+"_vectormap", tmp_map)