def evaluate(args, loader, generator, num_samples):
ade_outer, fde_outer = [], []
total_traj = 0
with torch.no_grad():
for batch in loader:
batch = [tensor.cuda() for tensor in batch]
(obs_traj, pred_traj_gt, obs_traj_rel, pred_traj_gt_rel,
non_linear_ped, loss_mask, seq_start_end) = batch
ade, fde = [], []
total_traj += pred_traj_gt.size(1)
for _ in range(num_samples):
pred_traj_fake_rel = generator(obs_traj, obs_traj_rel,
seq_start_end)
pred_traj_fake = relative_to_abs(pred_traj_fake_rel,
obs_traj[-1])
ade.append(
displacement_error(pred_traj_fake,
pred_traj_gt,
mode='raw'))
fde.append(
final_displacement_error(pred_traj_fake[-1],
pred_traj_gt[-1],
mode='raw'))
ade_sum = evaluate_helper(ade, seq_start_end)
fde_sum = evaluate_helper(fde, seq_start_end)
ade_outer.append(ade_sum)
fde_outer.append(fde_sum)
ade = sum(ade_outer) / (total_traj * args.pred_len)
fde = sum(fde_outer) / (total_traj)
return ade, fde
def evaluate(args, loader, generator):
trajs = []
ade_outer, fde_outer = [], []
total_traj = 0
with torch.no_grad():
for batch in loader:
batch = [tensor.cuda() for tensor in batch]
(obs_traj, pred_traj_gt, obs_traj_rel, pred_traj_gt_rel,
non_linear_ped, loss_mask, seq_start_end) = batch
total_traj += pred_traj_gt.size(1)
pred_traj_fake_rel = generator(obs_traj, obs_traj_rel,
seq_start_end)
pred_traj_fake = relative_to_abs(pred_traj_fake_rel, obs_traj[-1])
trajs.append([
obs_traj.cpu().numpy(),
pred_traj_fake.cpu().numpy(),
pred_traj_gt.cpu().numpy(),
seq_start_end.cpu().numpy()
])
ade_traj = displacement_error(pred_traj_fake,
pred_traj_gt,
mode='sum')
fde_traj = final_displacement_error(pred_traj_fake[-1],
pred_traj_gt[-1],
mode='sum')
ade_outer.append(ade_traj)
fde_outer.append(fde_traj)
ade = sum(ade_outer) / (total_traj * args.pred_len)
fde = sum(fde_outer) / total_traj
return ade, fde, trajs
def evaluate(args, loader, generator, num_samples):
ade_outer, fde_outer = [], []
total_traj = 0
with torch.no_grad():
ade_error, fde_error = [], []
for batch in loader:
batch = [tensor.cuda() for tensor in batch]
# print(len(batch))
(obs_traj, pred_traj_gt, obs_traj_rel, pred_traj_gt_rel,
obs_team_vec, obs_pos_vec, pred_team_vec, pred_pos_vec,
non_linear_ped, loss_mask, seq_start_end) = batch
ade, fde = [], []
total_traj += pred_traj_gt.size(1)
for _ in range(num_samples):
# pred_traj_fake_rel = generator(obs_traj, obs_traj_rel, seq_start_end) #regressor
pred_traj_fake_rel = generator(obs_traj, obs_traj_rel,
seq_start_end, obs_team_vec,
obs_pos_vec) # generator
pred_traj_fake = relative_to_abs(pred_traj_fake_rel,
obs_traj[-1])
ade.append(
displacement_error(pred_traj_fake,
pred_traj_gt,
mode='raw'))
fde.append(
final_displacement_error(pred_traj_fake[-1],
pred_traj_gt[-1],
mode='raw'))
# ade_error.append(ade.item())
# fde_error.append(fde.item())
ade_sum = evaluate_helper(ade, seq_start_end)
fde_sum = evaluate_helper(fde, seq_start_end)
ade_outer.append(ade_sum)
fde_outer.append(fde_sum)
ade = sum(ade_outer) / (total_traj * args.pred_len)
fde = sum(fde_outer) / (total_traj)
# print(len(ade_error),len(ade_error[0]))
# print(ade_error)
# print(sum(ade_error),sum(sum(ade_error)))
# print(total_traj,args.pred_len)
# ade_=sum(sum(ade_error)) / (total_traj * args.pred_len)
# fde_=sum(sum(fde_error))/ (total_traj * args.pred_len)
#
# print('ADE',ade_)
# print('FDE',fde_)
return ade, fde
def evaluate(args, loader, generatorSO, generatorST, discriminator,
num_samples):
ade_outer, fde_outer, kde_outer = [], [], []
total_traj = 0
with torch.no_grad():
for batch in loader:
batch = [tensor.cuda() for tensor in batch]
(obs_traj, pred_traj_gt, obs_traj_rel, pred_traj_gt_rel,
non_linear_ped, loss_mask, seq_start_end) = batch
ade, fde = [], []
total_traj += pred_traj_gt.size(1)
for _ in range(num_samples):
noise_input, noise_shape = generatorSO(obs_traj, obs_traj_rel,
seq_start_end)
with torch.enable_grad():
z_noise = MALA_corrected_sampler(generatorST,
discriminator, args,
noise_shape, noise_input,
seq_start_end, obs_traj,
obs_traj_rel)
decoder_h = torch.cat([noise_input, z_noise], dim=1)
decoder_h = torch.unsqueeze(decoder_h, 0)
generator_out = generatorST(decoder_h, seq_start_end, obs_traj,
obs_traj_rel)
pred_traj_fake_rel = generator_out
pred_traj_fake = relative_to_abs(pred_traj_fake_rel,
obs_traj[-1])
ade.append(
displacement_error(pred_traj_fake,
pred_traj_gt,
mode='raw'))
fde.append(
final_displacement_error(pred_traj_fake[-1],
pred_traj_gt[-1],
mode='raw'))
ade_sum = evaluate_helper(ade, seq_start_end)
fde_sum = evaluate_helper(fde, seq_start_end)
kde_sum = compute_kde_nll(pred_traj_fake, pred_traj_gt)
ade_outer.append(ade_sum)
fde_outer.append(fde_sum)
kde_outer.append(kde_sum)
ade = sum(ade_outer) / (total_traj * args.pred_len)
fde = sum(fde_outer) / (total_traj)
kde_nll = sum(kde_outer) / len(kde_outer)
return ade, fde, kde_nll
def evaluate(args, loader, generatorSO, generatorST, discriminator,
num_samples):
ade_outer, fde_outer = [], []
total_traj = 0
count_left = 0
count_mid = 0
count_right = 0
count = 0
with torch.no_grad():
for batch in loader:
batch = [tensor.cuda() for tensor in batch]
(obs_traj, pred_traj_gt, obs_traj_rel, pred_traj_gt_rel,
non_linear_ped, loss_mask, seq_start_end) = batch
ade, fde = [], []
total_traj += pred_traj_gt.size(1)
for _ in range(num_samples):
#TODO:替换generator
#将注释下一句换为注释下五句
#generator_out, z_noise = generator(obs_traj, obs_traj_rel, seq_start_end)
noise_input, noise_shape = generatorSO(obs_traj, obs_traj_rel,
seq_start_end)
with torch.enable_grad():
z_noise = MALA_corrected_sampler(generatorST,
discriminator, args,
noise_shape, noise_input,
seq_start_end, obs_traj,
obs_traj_rel)
decoder_h = torch.cat([noise_input, z_noise], dim=1)
decoder_h = torch.unsqueeze(decoder_h, 0)
generator_out = generatorST(decoder_h, seq_start_end, obs_traj,
obs_traj_rel)
pred_traj_fake_rel = generator_out
pred_traj_fake = relative_to_abs(pred_traj_fake_rel,
obs_traj[-1])
#---------------previous_tra,groundtruth_tra,predicted_tra--------------
window_num = obs_traj.size(1)
for i in range(window_num):
print("i:", i)
#-----------------------------------------------------
for ji in range(num_samples):
#----------pred_visualization-----------------------------------------------------------
predicted_tra = pred_traj_fake[:, i, :]
predicted_tra_x = predicted_tra[:, 0]
predicted_tra_y = predicted_tra[:, 1]
predicted_tra_x = predicted_tra_x.cpu()
predicted_tra_y = predicted_tra_y.cpu()
predicted_tra_x = predicted_tra_x.numpy()
predicted_tra_y = predicted_tra_y.numpy()
pred_x = predicted_tra_x[-1]
pred_y = predicted_tra_y[-1]
pred_last_pos = Point(pred_x, pred_y)
p1 = Point(-8, 8)
p2 = Point(8, 8)
left = Getlen(p1, pred_last_pos)
left = left.getlen()
right = Getlen(p2, pred_last_pos)
right = right.getlen()
if left >= right:
count_right += 1
else:
count_left += 1
#-----------------------------------------------------------------------------------------
print("第%d轮loader结束" % count)
count += 1
ade.append(
displacement_error(pred_traj_fake,
pred_traj_gt,
mode='raw'))
fde.append(
final_displacement_error(pred_traj_fake[-1],
pred_traj_gt[-1],
mode='raw'))
ade_sum = evaluate_helper(ade, seq_start_end)
fde_sum = evaluate_helper(fde, seq_start_end)
ade_outer.append(ade_sum)
fde_outer.append(fde_sum)
ade = sum(ade_outer) / (total_traj * args.pred_len)
fde = sum(fde_outer) / (total_traj)
return ade, fde, count_left, count_mid, count_right
# print(datasetss.obs_traj_rel[1:3].permute(2,0,1))
# print(datasetss.obs_traj[1:3].permute(2,0,1)[0])
abs_traj=relative_to_abs(predict.permute(2,0,1),test.pred_traj.permute(2,0,1)[0])
pred_traj= abs_traj.permute(1,0,2).numpy()
# print(pred_traj[1:4])
# print(datasetss.obs_traj[1:3])
# print(a)
# print(a.permute(1,0,2))
for i in range(110,115):
plt.plot(pred_traj[i][:,0], pred_traj[i][:,1], "r+")
plt.plot(test_x_abs[i][:,0], test_x_abs[i][:,1], "b+")
plt.plot(test_y_abs[i][:,0], test_y_abs[i][:,1], "g+")
plt.show()
pred_traj_tensor=torch.from_numpy(pred_traj)
gt_tensor=torch.from_numpy(test_y_abs)
ade=displacement_error(pred_traj_tensor.permute(1,0,2),gt_tensor.permute(1,0,2),mode="sum")
# print(ade)
ade_res = (ade[0].detach()) / (len(pred_traj) * 12)
print(ade_res)
fde= final_displacement_error(pred_traj_tensor.permute(1,0,2)[-1],gt_tensor.permute(1,0,2)[-1],mode="sum")
fde_res= (fde[0].detach()) / (len(pred_traj))
# print(predict.permute(2,0,1))
# print(test.pred_traj.permute(2,0,1))
print(fde_res)
print(test_y_abs.shape)
print(pred_traj_tensor.shape)
def evaluate(args, loader, generator, num_samples, collisionThreshold):
ade_outer, fde_outer = [], []
total_traj = 0
with torch.no_grad():
testSetStatistics = {}
collisionStatistics = {}
poolingStatistics = collections.Counter(), collections.Counter(
), collections.Counter(), collections.Counter()
for batch in loader:
if evalArgs.use_gpu:
batch = [tensor.cuda() for tensor in batch]
else:
batch = [tensor.cpu() for tensor in batch]
(obs_traj, pred_traj_gt, obs_traj_rel, pred_traj_gt_rel,
non_linear_ped, loss_mask, seq_start_end) = batch
def updateTestSetStatistics():
dirOfCurrentTestSet = loader.dataset.data_dir
if (dirOfCurrentTestSet not in testSetStatistics):
testSetStatistics[dirOfCurrentTestSet] = (
0, collections.Counter(), 0)
currNumOfScenes, pedestriansPerScene, currNumOfBatches = testSetStatistics[
dirOfCurrentTestSet]
newNumOfScenes = currNumOfScenes + len(seq_start_end)
newNumOfBatches = currNumOfBatches + 1
for start, end in seq_start_end:
start = start.item()
end = end.item()
numPedestriansInScene = end - start
pedestriansPerScene[numPedestriansInScene] += 1
testSetStatistics[dirOfCurrentTestSet] = (newNumOfScenes,
pedestriansPerScene,
newNumOfBatches)
updateTestSetStatistics()
ade, fde, poolStats = [], [], []
total_traj += pred_traj_gt.size(1)
for _ in range(num_samples):
pred_traj_fake_rel, currPoolingStatistics = generator(
obs_traj, obs_traj_rel, seq_start_end)
poolingStatistics = tuple(
oldStats + newStats for oldStats, newStats in zip(
poolingStatistics, currPoolingStatistics))
pred_traj_fake = relative_to_abs(pred_traj_fake_rel,
obs_traj[-1])
start, end = seq_start_end[1]
exampleSituation = obs_traj[:, start:
end, :], pred_traj_fake[:, start:
end, :], pred_traj_gt[:,
start:
end, :]
def updateCollisionStatistics():
allCoordOfFrame0 = pred_traj_fake[0]
allCoordFrame0Situation0 = allCoordOfFrame0
for _, (start, end) in enumerate(seq_start_end):
start = start.item()
end = end.item()
totalNumOfCollisions = 0
for currFrame in pred_traj_fake:
currPedestrians = currFrame[start:end]
currPedestrians = np.asarray(currPedestrians)
pedestrianDistances = cdist(
currPedestrians, currPedestrians)
upperTriangle = sum([
pedestrianDistances[i][j]
for i in range(1, len(pedestrianDistances))
for j in range(i)
])
lowerTriangle = sum([
pedestrianDistances[i][j]
for i in range(len(pedestrianDistances))
for j in range(i + 1, len(pedestrianDistances))
])
assert upperTriangle - lowerTriangle < .000001, 'UpperSum = {}, LowerSum = {}'.format(
upperTriangle, lowerTriangle)
numCollisions = [
pedestrianDistances[i][j] <= collisionThreshold
for i in range(1, len(pedestrianDistances))
for j in range(i)
].count(True)
totalNumOfCollisions += numCollisions
dirOfCurrentTestSet = loader.dataset.data_dir
if (dirOfCurrentTestSet not in collisionStatistics):
collisionStatistics[dirOfCurrentTestSet] = (0, 0,
[])
currNumOfCollisions, currTotalNumOfSituations, currCollisionSituations = collisionStatistics[
dirOfCurrentTestSet]
newNumOfCollisions = currNumOfCollisions + totalNumOfCollisions
if (newNumOfCollisions > currNumOfCollisions):
currSituation = (obs_traj[:, start:end, :],
pred_traj_fake[:, start:end, :],
pred_traj_gt[:, start:end, :])
currCollisionSituations.append(currSituation)
collisionStatistics[dirOfCurrentTestSet] = (
newNumOfCollisions, currTotalNumOfSituations + 1,
currCollisionSituations)
updateCollisionStatistics()
ade.append(
displacement_error(pred_traj_fake,
pred_traj_gt,
mode='raw'))
fde.append(
final_displacement_error(pred_traj_fake[-1],
pred_traj_gt[-1],
mode='raw'))
ade_sum = evaluate_helper(ade, seq_start_end)
fde_sum = evaluate_helper(fde, seq_start_end)
ade_outer.append(ade_sum)
fde_outer.append(fde_sum)
ade = sum(ade_outer) / (total_traj * args.pred_len)
fde = sum(fde_outer) / (total_traj)
return ade, fde, testSetStatistics, poolingStatistics, collisionStatistics
def evaluate(args, loader, generator, num_samples):
ade_outer, fde_outer = [], []
total_traj = 0
i = 0
fig = plt.figure()
ax = fig.add_axes([0.1, 0.1, 0.75, 0.75])
generator.eval()
with torch.no_grad():
for batch in loader:
i = i + 1
batch = [tensor.cuda() for tensor in batch]
(obs_traj, pred_traj_gt, obs_traj_rel, pred_traj_gt_rel,
non_linear_ped, loss_mask, seq_start_end) = batch
# print("Trajs: ")
# print(obs_traj[:,0,:])
# print(obs_traj_rel[:,0,:])
ade, fde = [], []
total_traj += pred_traj_gt.size(1)
print(num_samples)
for rr in range(num_samples):
pred_traj_fake_rel = generator(obs_traj, obs_traj_rel,
seq_start_end)
pred_traj_fake = relative_to_abs(pred_traj_fake_rel,
obs_traj[-1])
pred_traj_fake_plot = pred_traj_fake.permute(1, 0, 2)
pred_traj_fake_plot_single = pred_traj_fake_plot[
0, :, :].cpu().numpy()
# print(pred_traj_fake_plot_single.shape)
if i < 25:
pred_traj_fake_permuted = pred_traj_fake.permute(1, 0, 2)
pred_traj_gt_permuted = pred_traj_gt.permute(1, 0, 2)
obs_traj_permuted = obs_traj.permute(1, 0, 2)
# if k == 0:
# view_traj(ax, pred_traj_fake_permuted[0,:,:], pred_traj_gt_permuted[0,:,:], obs_traj_permuted[0,:,:], args, all_three=True)
# else:
yy = 0
view_traj(ax, pred_traj_fake_permuted[yy, :, :],
pred_traj_gt_permuted[yy, :, :],
obs_traj_permuted[yy, :, :], args)
# plt.plot(pred_traj_fake_plot_single[:,0], pred_traj_fake_plot_single[:,1])
ade.append(
displacement_error(pred_traj_fake,
pred_traj_gt,
mode='raw'))
fde.append(
final_displacement_error(pred_traj_fake[-1],
pred_traj_gt[-1],
mode='raw'))
ade_sum = evaluate_helper(ade, seq_start_end)
fde_sum = evaluate_helper(fde, seq_start_end)
ade_outer.append(ade_sum)
fde_outer.append(fde_sum)
# plt.xlim((0,17))
# plt.ylim((-10,10))
# plt.legend()
if i < 25:
plt.show()
plt.cla()
ade = sum(ade_outer) / (total_traj * args.pred_len)
fde = sum(fde_outer) / (total_traj)
return ade, fde
def evaluate(args, loader, generator, num_samples):
ade_outer, fde_outer = [], []
total_traj = 0
fig, ax = plt.subplots(num='3d time-surface', figsize=(16, 12))
topleft = (103.80, 1.21)
bottomright = (103.86, 1.16)
def plotrectangle(ax, topleft, bottomright):
x1 = topleft[0]
y1 = topleft[1]
x2 = bottomright[0]
y2 = bottomright[1]
bordercol = 'black'
borderalpha = 0.6
ax.plot([x1, x2], [y1, y1], color=bordercol, alpha=borderalpha)
ax.plot([x1, x2], [y2, y2], color=bordercol, alpha=borderalpha)
ax.plot([x1, x1], [y1, y2], color=bordercol, alpha=borderalpha)
ax.plot([x2, x2], [y1, y2], color=bordercol, alpha=borderalpha)
plotrectangle(ax, topleft, bottomright)
cols = ['b', 'b', 'b', 'b']
colid = 0
with torch.no_grad():
for batch in loader:
batch = [tensor.cuda() for tensor in batch]
(obs_traj, pred_traj_gt, obs_traj_rel, pred_traj_gt_rel,
non_linear_ped, loss_mask, seq_start_end) = batch
ade, fde = [], []
total_traj += pred_traj_gt.size(1)
np_obs_traj = obs_traj.cpu().detach().numpy()
np_pred_traj_gt = pred_traj_gt.cpu().detach().numpy()
print("np_pred_traj_gt.shape", np_pred_traj_gt.shape)
print("np_obs_traj[-1,:,:].shape", np_obs_traj[-1:, :, :].shape)
np_pred_traj_gt = np.concatenate(
(np_obs_traj[-1:, :, :], np_pred_traj_gt), axis=0)
# np_pred_traj_gt reshape(,33,2)
plottraj(ax, np_obs_traj, 'obs_traj', cols[colid], alpha=1.0)
colid = (colid + 1) % 4
plottraj(ax, np_pred_traj_gt, 'pred_traj_gt', 'g', alpha=1.0)
for _ in range(num_samples):
pred_traj_fake_rel = generator(obs_traj, obs_traj_rel,
seq_start_end)
pred_traj_fake = relative_to_abs(pred_traj_fake_rel,
obs_traj[-1])
ade.append(
displacement_error(pred_traj_fake,
pred_traj_gt,
mode='raw'))
fde.append(
final_displacement_error(pred_traj_fake[-1],
pred_traj_gt[-1],
mode='raw'))
np_pred_traj_fake = pred_traj_fake.cpu().detach().numpy()
np_pred_traj_fake = np.concatenate(
(np_obs_traj[-1:, :, :], np_pred_traj_fake), axis=0)
plottraj(ax, np_pred_traj_fake, 'pred_traj_fake', 'r')
ade_sum = evaluate_helper(ade, seq_start_end)
fde_sum = evaluate_helper(fde, seq_start_end)
ade_outer.append(ade_sum)
fde_outer.append(fde_sum)
break
ade = sum(ade_outer) / (total_traj * args.pred_len)
fde = sum(fde_outer) / (total_traj)
print("ade ", ade)
plt.legend(bbox_to_anchor=(1.0, 1.1),
loc='upper left',
title="legend",
borderaxespad=0.)
# ax.autoscale(False)
ax.set_aspect('equal')
# plt.show()
plt.savefig('img' + global_model_path + '.png')
return ade, fde
for batch in tqdm(loader):
batch = [tensor.cuda() for tensor in batch]
(obs_traj, pred_traj_gt, obs_traj_rel, pred_traj_gt_rel, obs_team_vec,
obs_pos_vec, pred_team_vec, pred_pos_vec, non_linear_ped, loss_mask,
seq_start_end) = batch
pred_traj_fake_rel = generator(obs_traj, obs_traj_rel, seq_start_end,
obs_team_vec, obs_pos_vec) # generator
pred_traj_fake = relative_to_abs(pred_traj_fake_rel, obs_traj[-1])
# print(seq_start_end)
start, end = seq_start_end[0][0], seq_start_end[0][1]
if end - start != 11:
continue
ade = displacement_error(pred_traj_fake, pred_traj_gt,
mode='raw') # batch*11
fde = final_displacement_error(pred_traj_fake[-1],
pred_traj_gt[-1],
mode='raw') # batch*11
obs_traj_list.append(obs_traj.cpu().numpy().reshape(
8, -1, 11, 2)) # obs_len * (batch*11) * 2
pred_traj_gt_list.append(pred_traj_gt.cpu().numpy().reshape(
8, -1, 11, 2))
pred_traj_fake_list.append(pred_traj_fake.cpu().numpy().reshape(
8, -1, 11, 2))
pos_vec_list.append(obs_pos_vec.cpu().numpy().reshape(8, -1, 11, 4))
team_vec_list.append(obs_team_vec.cpu().numpy().reshape(8, -1, 11, 3))
seq_start_end_list.append(seq_start_end.cpu().numpy()) # Batch * 2
def cal_ade(pred_traj_gt, pred_traj_fake, linear_ped, non_linear_ped, loss_mask):
ade = displacement_error(pred_traj_fake, pred_traj_gt, mask=loss_mask)
ade_l = displacement_error(pred_traj_fake, pred_traj_gt, linear_ped, mask=loss_mask)
ade_nl = displacement_error(pred_traj_fake, pred_traj_gt, non_linear_ped, mask=loss_mask)
return ade, ade_l, ade_nl
def evaluate(args, loader, generator, num_samples):
ade_outer, fde_outer = [], []
total_traj = 0
count_left = 0
count_mid = 0
count_right = 0
count = 0
with torch.no_grad():
for batch in loader:
batch = [tensor.cuda() for tensor in batch]
(obs_traj, pred_traj_gt, obs_traj_rel, pred_traj_gt_rel,
non_linear_ped, loss_mask, seq_start_end) = batch
ade, fde = [], []
total_traj += pred_traj_gt.size(1)
#---------------previous_tra,groundtruth_tra,predicted_tra--------------
window_num = obs_traj.size(1)
for i in range(window_num):
print(i)
#-----------------------------------------------------
for ji in range(num_samples):
pred_traj_fake_rel = generator(obs_traj, obs_traj_rel,
seq_start_end)
pred_traj_fake = relative_to_abs(pred_traj_fake_rel,
obs_traj[-1])
#----------visualization-----------------------------------------------------------
predicted_tra = pred_traj_fake[:, i, :]
predicted_tra_x = predicted_tra[:, 0]
predicted_tra_y = predicted_tra[:, 1]
predicted_tra_x = predicted_tra_x.cpu()
predicted_tra_y = predicted_tra_y.cpu()
predicted_tra_x = predicted_tra_x.numpy()
predicted_tra_y = predicted_tra_y.numpy()
pred_x = predicted_tra_x[-1]
pred_y = predicted_tra_y[-1]
pred_last_pos = Point(pred_x, pred_y)
p1 = Point(-8, 16)
p2 = Point(8, 16)
left = Getlen(p1, pred_last_pos)
left = left.getlen()
right = Getlen(p2, pred_last_pos)
right = right.getlen()
#ipdb.set_trace()
if -1.5 < pred_x < 1.8:
count_mid += 1
else:
if left >= right:
count_right += 1
else:
count_left += 1
#----------------------------------------------------------------------------------
ade.append(
displacement_error(pred_traj_fake,
pred_traj_gt,
mode='raw'))
fde.append(
final_displacement_error(pred_traj_fake[-1],
pred_traj_gt[-1],
mode='raw'))
ade_sum = evaluate_helper(ade, seq_start_end)
fde_sum = evaluate_helper(fde, seq_start_end)
ade_outer.append(ade_sum)
fde_outer.append(fde_sum)
print("第%d轮batch结束" % count)
count += 1
ade = sum(ade_outer) / (total_traj * args.pred_len)
fde = sum(fde_outer) / (total_traj)
return ade, fde, count_left, count_mid, count_right
def evaluate(args, loader, generator, num_samples, plot=True):
ade_outer, fde_outer = [], []
total_traj = 0
count = 0
with torch.no_grad():
for batch in loader:
count += 1
batch = [tensor.cuda() for tensor in batch]
(obs_traj, pred_traj_gt, obs_traj_rel, pred_traj_gt_rel,
non_linear_ped, loss_mask, seq_start_end) = batch
ade, fde = [], []
total_traj += pred_traj_gt.size(1)
for _ in range(num_samples):
pred_traj_fake_rel = generator(obs_traj, obs_traj_rel,
seq_start_end)
pred_traj_fake = relative_to_abs(pred_traj_fake_rel,
obs_traj[-1])
ade.append(
displacement_error(pred_traj_fake,
pred_traj_gt,
mode='raw'))
fde.append(
final_displacement_error(pred_traj_fake[-1],
pred_traj_gt[-1],
mode='raw'))
# add plot module
if plot:
_plot_dir = '../saves/'
if not os.path.exists(_plot_dir):
os.makedirs(_plot_dir)
fig = plt.figure()
whole_traj_fake = torch.cat([obs_traj, pred_traj_fake],
dim=0)
whole_traj_fake = whole_traj_fake[:, 0, :]
whole_traj_gt = torch.cat([obs_traj, pred_traj_gt], dim=0)
whole_traj_gt = whole_traj_gt[:, seq_start_end[0][0]:
seq_start_end[0][1], :]
y_upper_limit = max([
torch.max(whole_traj_fake[:, 1]).data,
torch.max(whole_traj_gt[:, :, 1]).data
]) + 1.
y_lower_limit = min([
torch.min(whole_traj_fake[:, 1]).data,
torch.min(whole_traj_gt[:, :, 1]).data
]) - 1.
x_upper_limit = max([
torch.max(whole_traj_fake[:, 0]).data,
torch.max(whole_traj_gt[:, :, 0]).data
]) + 1.
x_lower_limit = min([
torch.min(whole_traj_fake[:, 0]).data,
torch.min(whole_traj_gt[:, :, 0]).data
]) - 1.
def plot_time_step(i):
fig, ax = plt.subplots()
# ax.plot(goal_point[0].cpu().numpy(), goal_point[1].cpu().numpy(), 'gx')
# plot last three point
gt_points_x = whole_traj_gt[max(i - 2, 0):i + 1, :,
0].cpu().numpy().flatten()
gt_points_y = whole_traj_gt[max(i - 2, 0):i + 1, :,
1].cpu().numpy().flatten()
ax.plot(gt_points_x, gt_points_y, 'b.')
fake_points_x = whole_traj_fake[max(i - 2, 0):i + 1,
0].cpu().numpy()
fake_points_y = whole_traj_fake[max(i - 2, 0):i + 1,
1].cpu().numpy()
if i >= args.obs_len:
ax.plot(fake_points_x, fake_points_y, 'r*')
else:
ax.plot(fake_points_x, fake_points_y, 'g.')
ax.set_ylim(y_lower_limit.cpu(), y_upper_limit.cpu())
ax.set_xlim(x_lower_limit.cpu(), x_upper_limit.cpu())
fig.canvas.draw()
image = np.frombuffer(fig.canvas.tostring_rgb(),
dtype='uint8')
image = image.reshape(
fig.canvas.get_width_height()[::-1] + (3, ))
plt.close(fig)
return image
imageio.mimsave(_plot_dir + str(count) + '.gif', [
plot_time_step(i)
for i in range(args.obs_len + args.pred_len)
],
fps=2)
ade_sum = evaluate_helper(ade, seq_start_end)
fde_sum = evaluate_helper(fde, seq_start_end)
ade_outer.append(ade_sum)
fde_outer.append(fde_sum)
ade = sum(ade_outer) / (total_traj * args.pred_len)
fde = sum(fde_outer) / (total_traj)
return ade, fde
def evaluate(args, loader, generator, num_samples, path):
# ade_outer, fde_outer = [], []
ade_all, fde_all = AverageMeter(), AverageMeter()
total_obj = 0
pred_len = args.pred_len
dataset_name = args.dataset_name
obj_class = dataset_name.split('_')[1][:3]
save_dir, _, _ = fileparts(path)
save_dir = os.path.join(save_dir, 'results_%s' % get_timestring())
mkdir_if_missing(save_dir)
result_file_single = os.path.join(save_dir, 'results.json')
result_dict = dict()
with torch.no_grad():
for batch in loader:
batch = [tensor.cuda() for tensor in batch]
(obs_traj, pred_traj_gt, obs_traj_rel, pred_traj_gt_rel,
non_linear_ped, loss_mask, seq_start_end, id_frame) = batch
# obs_traj frames x objects x 2
# pred_traj_gt frames x objects x 2
# seq_Start_end start, end of ped index in each timestamp, used for pooling at every timestamp
# id_frame 2frames x objects x 3
# loss_mask objects x 2frames
num_obs = obs_traj.size(0)
num_objects = obs_traj.size(1)
id_frame_pred = id_frame[num_obs:] # frames x obj x 3
loss_mask_pred = loss_mask[:, num_obs:] # objects x seq_len
ade, fde = [], []
for sample_index in range(num_samples):
pred_traj_fake_rel = generator(obs_traj, obs_traj_rel,
seq_start_end)
pred_traj_fake = relative_to_abs(
pred_traj_fake_rel, obs_traj[-1]) # frames x objects x 2
# save results
for object_index in range(num_objects):
id_frame_tmp = id_frame_pred[:, object_index, :]
frame = int(id_frame_tmp[0, 0].item())
# seqname should be the same across frames
seq = np.unique(id_frame_tmp[:, -1].cpu().clone().numpy())
assert len(seq) == 1, 'error'
seqname = int2seqname(seq[0]) # AIODrive only
# seqname should be the same across frames
ID = np.unique(id_frame_tmp[:, 1].cpu().clone().numpy())
assert len(ID) == 1, 'error'
ID = int(ID[0])
# saving to individual frames
final_results = torch.cat([
id_frame_tmp[:, :2], pred_traj_fake[:, object_index, :]
],
axis=-1).cpu().clone().numpy()
save_path = os.path.join(
save_dir, seqname, 'frame_%06d' % (frame),
'sample_%03d' % sample_index + '.txt')
mkdir_if_missing(save_path)
with open(save_path, 'a') as f:
np.savetxt(f, final_results, fmt="%.3f")
# saving to a single file, result format
# {seqname1: {frame1: {sample1: {ID1: {state: N x 2, prob: 1}}}, seqname2, ...}
if seqname not in result_dict.keys():
result_dict[seqname] = dict()
if frame not in result_dict[seqname].keys():
result_dict[seqname][frame] = dict()
if sample_index not in result_dict[seqname][frame].keys():
result_dict[seqname][frame][sample_index] = dict()
if ID not in result_dict[seqname][frame][
sample_index].keys():
result_dict[seqname][frame][sample_index][ID] = dict()
result_dict[seqname][frame][sample_index][
ID]['state'] = pred_traj_fake[:, object_index, :].cpu(
).clone().numpy().tolist()
result_dict[seqname][frame][sample_index][ID]['prob'] = 1.0
# compute ADE
ade_tmp = displacement_error(
pred_traj_fake,
pred_traj_gt,
mode='raw',
mask=loss_mask_pred
) # list of ade for each object in the batch
ade.append(ade_tmp) # list of error for all samples
# select the right last timestamp for FDE computation, i.e., not select the last frame if masked out
pred_traj_last = []
gt_traj_last = []
for obj_tmp in range(num_objects):
loss_mask_tmp = loss_mask_pred[obj_tmp] # seq_len
good_index = torch.nonzero(loss_mask_tmp)
if torch.nonzero(loss_mask_tmp).size(0) == 0:
pred_traj_last.append(torch.zeros(2).cuda() / 0)
gt_traj_last.append(torch.zeros(2).cuda() / 0)
else:
last_index = torch.max(good_index)
pred_traj_last.append(pred_traj_fake[last_index,
obj_tmp, :])
gt_traj_last.append(pred_traj_gt[last_index,
obj_tmp, :])
gt_traj_last = torch.stack(gt_traj_last, dim=0) # num_obj x 2
pred_traj_last = torch.stack(pred_traj_last,
dim=0) # num_obj x 2
# compute FDE
fde_tmp = final_displacement_error(pred_traj_last,
gt_traj_last,
mode='raw')
fde.append(fde_tmp) # list of error for all samples
# select the one sample with the minimum errors, remove nan
num_invalid = torch.sum(torch.isnan(ade_tmp))
num_valid = pred_traj_gt.size(1) - num_invalid
total_obj += num_valid # only add No.obj if it is valid, not all future frames are padded
ade_ave, num_obj = best_of_K(ade, seq_start_end, err_type='ADE')
fde_ave, num_obj = best_of_K(fde, seq_start_end, err_type='FDE')
ade_all.update(ade_ave, n=num_obj)
fde_all.update(fde_ave, n=num_obj)
actual_len = pred_len * args.skip
final_dict = {actual_len: {obj_class: result_dict}}
with open(result_file_single, 'w') as outfile:
json.dump(final_dict, outfile)
return ade_all.avg, fde_all.avg
def evaluate(args, loader, generator, num_samples):
ade_outer, fde_outer = [], []
total_traj = 0
# plt 2021-02
plt.figure(num='global map', figsize=(8, 10))
plt.axis('equal')
plt.xlabel("x")
plt.ylabel("y")
plt.title('Global')
plt.pause(1)
with torch.no_grad(): # dont calculate grad
for batch in loader:
# batch = [tensor.cuda() for tensor in batch]
# obs_traj[num, x_size, y_size]-[:,0,0],[:,0,1]为一条轨迹坐标
batch = [tensor for tensor in batch]
(obs_traj, pred_traj_gt, obs_traj_rel, pred_traj_gt_rel,
non_linear_ped, loss_mask, seq_start_end) = batch
ade, fde = [], []
total_traj += pred_traj_gt.size(1)
for _ in range(num_samples):
pred_traj_fake_rel = generator(
obs_traj,
obs_traj_rel,
seq_start_end # run TrajectoryGenerator
) # 预测-未来轨迹-相对坐标
pred_traj_fake = relative_to_abs(pred_traj_fake_rel,
obs_traj[-1])
ade.append(
displacement_error(pred_traj_fake,
pred_traj_gt,
mode='raw'))
fde.append(
final_displacement_error(pred_traj_fake[-1],
pred_traj_gt[-1],
mode='raw'))
# plt 2021-02
plt.pause(1)
plt.cla()
center_point = obs_traj[-1, 0:2, 0]
plt_axis = [
center_point[0] - 15, center_point[0] + 15,
center_point[1] - 15, center_point[1] + 15
]
for index in range(seq_start_end[0, 0], seq_start_end[0, 1]):
# obs_traj
plt.plot(obs_traj[:, index, 0],
obs_traj[:, index, 1],
c='gray',
linestyle='--')
# pred_traj_fake
plt.plot(pred_traj_fake[:, index, 0],
pred_traj_fake[:, index, 1],
c='blue',
linestyle='-.')
# pred_traj_gt
plt.plot(pred_traj_gt[:, index, 0],
pred_traj_gt[:, index, 1],
c='black',
linestyle='--')
plt.axis('equal')
plt.axis(plt_axis)
ade_sum = evaluate_helper(ade, seq_start_end)
fde_sum = evaluate_helper(fde, seq_start_end)
ade_outer.append(ade_sum)
fde_outer.append(fde_sum)
ade = sum(ade_outer) / (total_traj * args.pred_len)
fde = sum(fde_outer) / (total_traj)
return ade, fde
def cal_ade(pred_traj_gt, pred_traj_fake, linear_ped, non_linear_ped):
ade = displacement_error(pred_traj_fake, pred_traj_gt)
ade_l = displacement_error(pred_traj_fake, pred_traj_gt, linear_ped)
ade_nl = displacement_error(pred_traj_fake, pred_traj_gt, non_linear_ped)
return ade, ade_l, ade_nl
def cal_ade(pred_traj_gt, pred_traj_fake, linear_ped, non_linear_ped):
ade = displacement_error(pred_traj_fake, pred_traj_gt)
ade_l = displacement_error(pred_traj_fake, pred_traj_gt, linear_ped)
ade_nl = displacement_error(pred_traj_fake, pred_traj_gt, non_linear_ped)
return ade, ade_l, ade_nl #sum over minibatch, one number
