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lstm_baseline.py
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lstm_baseline.py
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from __future__ import division
from __future__ import print_function
import time
import argparse
import pickle
import os
import datetime
import torch.optim as optim
from torch.optim import lr_scheduler
from utils import *
from modules import *
parser = argparse.ArgumentParser()
parser.add_argument('--no-cuda', action='store_true', default=False,
help='Disables CUDA training.')
parser.add_argument('--seed', type=int, default=42, help='Random seed.')
parser.add_argument('--epochs', type=int, default=500,
help='Number of epochs to train.')
parser.add_argument('--batch-size', type=int, default=128,
help='Number of samples per batch.')
parser.add_argument('--lr', type=float, default=0.0005,
help='Initial learning rate.')
parser.add_argument('--hidden', type=int, default=256,
help='Number of hidden units.')
parser.add_argument('--num_atoms', type=int, default=5,
help='Number of atoms in simulation.')
parser.add_argument('--num-layers', type=int, default=2,
help='Number of LSTM layers.')
parser.add_argument('--suffix', type=str, default='_springs',
help='Suffix for training data (e.g. "_charged".')
parser.add_argument('--dropout', type=float, default=0.0,
help='Dropout rate (1 - keep probability).')
parser.add_argument('--log-interval', type=int, default=10, metavar='N',
help='How many batches to wait before logging.')
parser.add_argument('--save-folder', type=str, default='logs',
help='Where to save the trained model.')
parser.add_argument('--load-folder', type=str, default='',
help='Where to load the trained model if finetunning. ' +
'Leave empty to train from scratch')
parser.add_argument('--dims', type=int, default=4,
help='The number of dimensions (position + velocity).')
parser.add_argument('--timesteps', type=int, default=49,
help='The number of time steps per sample.')
parser.add_argument('--prediction-steps', type=int, default=10, metavar='N',
help='Num steps to predict before using teacher forcing.')
parser.add_argument('--lr-decay', type=int, default=200,
help='After how epochs to decay LR by a factor of gamma.')
parser.add_argument('--gamma', type=float, default=0.5,
help='LR decay factor.')
parser.add_argument('--motion', action='store_true', default=False,
help='Use motion capture data loader.')
parser.add_argument('--non-markov', action='store_true', default=False,
help='Use non-Markovian evaluation setting.')
parser.add_argument('--var', type=float, default=5e-5,
help='Output variance.')
args = parser.parse_args()
args.cuda = not args.no_cuda and torch.cuda.is_available()
print(args)
np.random.seed(args.seed)
torch.manual_seed(args.seed)
if args.cuda:
torch.cuda.manual_seed(args.seed)
log = None
# Save model and meta-data. Always saves in a new folder.
if args.save_folder:
exp_counter = 0
now = datetime.datetime.now()
timestamp = now.isoformat()
save_folder = '{}/exp{}/'.format(args.save_folder, timestamp)
while os.path.isdir(save_folder):
exp_counter += 1
save_folder = os.path.join(args.save_folder,
'exp{}'.format(exp_counter))
os.mkdir(save_folder)
meta_file = os.path.join(save_folder, 'metadata.pkl')
model_file = os.path.join(save_folder, 'model.pt')
log_file = os.path.join(save_folder, 'log.txt')
log = open(log_file, 'w')
pickle.dump({'args': args}, open(meta_file, "wb"))
else:
print("WARNING: No save_folder provided!" +
"Testing (within this script) will throw an error.")
train_loader, valid_loader, test_loader, loc_max, loc_min, vel_max, vel_min = load_data(
args.batch_size, args.suffix)
class RecurrentBaseline(nn.Module):
"""LSTM model for joint trajectory prediction."""
def __init__(self, n_in, n_hid, n_out, n_atoms, n_layers, do_prob=0.):
super(RecurrentBaseline, self).__init__()
self.fc1_1 = nn.Linear(n_in, n_hid)
self.fc1_2 = nn.Linear(n_hid, n_hid)
self.rnn = nn.LSTM(n_atoms * n_hid, n_atoms * n_hid, n_layers)
self.fc2_1 = nn.Linear(n_atoms * n_hid, n_atoms * n_hid)
self.fc2_2 = nn.Linear(n_atoms * n_hid, n_atoms * n_out)
self.bn = nn.BatchNorm1d(n_out)
self.dropout_prob = do_prob
self.init_weights()
def init_weights(self):
for m in self.modules():
if isinstance(m, nn.Linear):
nn.init.xavier_normal(m.weight.data)
m.bias.data.fill_(0.1)
elif isinstance(m, nn.BatchNorm1d):
m.weight.data.fill_(1)
m.bias.data.zero_()
def batch_norm(self, inputs):
x = inputs.view(inputs.size(0) * inputs.size(1), -1)
x = self.bn(x)
return x.view(inputs.size(0), inputs.size(1), -1)
def step(self, ins, hidden=None):
# Input shape: [num_sims, n_atoms, n_in]
x = F.relu(self.fc1_1(ins))
x = F.dropout(x, self.dropout_prob, training=self.training)
x = F.relu(self.fc1_2(x))
x = x.view(ins.size(0), -1)
# [num_sims, n_atoms*n_hid]
x = x.unsqueeze(0)
x, hidden = self.rnn(x, hidden)
x = x[0, :, :]
x = F.relu(self.fc2_1(x))
x = self.fc2_2(x)
# [num_sims, n_out*n_atoms]
x = x.view(ins.size(0), ins.size(1), -1)
# [num_sims, n_atoms, n_out]
# Predict position/velocity difference
x = x + ins
return x, hidden
def forward(self, inputs, prediction_steps, burn_in=False, burn_in_steps=1):
# Input shape: [num_sims, num_things, num_timesteps, n_in]
outputs = []
hidden = None
for step in range(0, inputs.size(2) - 1):
if burn_in:
if step <= burn_in_steps:
ins = inputs[:, :, step, :]
else:
ins = outputs[step - 1]
else:
# Use ground truth trajectory input vs. last prediction
if not step % prediction_steps:
ins = inputs[:, :, step, :]
else:
ins = outputs[step - 1]
output, hidden = self.step(ins, hidden)
# Predict position/velocity difference
outputs.append(output)
outputs = torch.stack(outputs, dim=2)
return outputs
model = RecurrentBaseline(args.dims, args.hidden, args.dims,
args.num_atoms, args.num_layers, args.dropout)
if args.load_folder:
model_file = os.path.join(args.load_folder, 'model.pt')
model.load_state_dict(torch.load(model_file))
args.save_folder = False
optimizer = optim.Adam(list(model.parameters()), lr=args.lr)
scheduler = lr_scheduler.StepLR(optimizer, step_size=args.lr_decay,
gamma=args.gamma)
# Linear indices of an upper triangular mx, used for loss calculation
triu_indices = get_triu_offdiag_indices(args.num_atoms)
if args.cuda:
model.cuda()
def nll_gaussian(preds, target, variance, add_const=False):
neg_log_p = ((preds - target) ** 2 / (2 * variance))
if add_const:
const = 0.5 * np.log(2 * np.pi * variance)
neg_log_p += const
return neg_log_p.sum() / (target.size(0) * target.size(1))
def train(epoch, best_val_loss):
t = time.time()
loss_train = []
loss_val = []
mse_baseline_train = []
mse_baseline_val = []
mse_train = []
mse_val = []
model.train()
scheduler.step()
for batch_idx, (data, relations) in enumerate(train_loader):
if args.cuda:
data, relations = data.cuda(), relations.cuda()
data, relations = Variable(data), Variable(relations)
optimizer.zero_grad()
output = model(data, 100,
burn_in=True,
burn_in_steps=args.timesteps - args.prediction_steps)
target = data[:, :, 1:, :]
loss = nll_gaussian(output, target, args.var)
mse = F.mse_loss(output, target)
mse_baseline = F.mse_loss(data[:, :, :-1, :], data[:, :, 1:, :])
loss.backward()
optimizer.step()
loss_train.append(loss.data[0])
mse_train.append(mse.data[0])
mse_baseline_train.append(mse_baseline.data[0])
model.eval()
for batch_idx, (data, relations) in enumerate(valid_loader):
if args.cuda:
data, relations = data.cuda(), relations.cuda()
data, relations = Variable(data, requires_grad=False), Variable(
relations, requires_grad=False)
output = model(data, 1)
target = data[:, :, 1:, :]
loss = nll_gaussian(output, target, args.var)
mse = F.mse_loss(output, target)
mse_baseline = F.mse_loss(data[:, :, :-1, :], data[:, :, 1:, :])
loss_val.append(loss.data[0])
mse_val.append(mse.data[0])
mse_baseline_val.append(mse_baseline.data[0])
print('Epoch: {:04d}'.format(epoch),
'nll_train: {:.10f}'.format(np.mean(loss_train)),
'mse_train: {:.12f}'.format(np.mean(mse_train)),
'mse_baseline_train: {:.10f}'.format(np.mean(mse_baseline_train)),
'nll_val: {:.10f}'.format(np.mean(loss_val)),
'mse_val: {:.12f}'.format(np.mean(mse_val)),
'mse_baseline_val: {:.10f}'.format(np.mean(mse_baseline_val)),
'time: {:.4f}s'.format(time.time() - t))
if args.save_folder and np.mean(loss_val) < best_val_loss:
torch.save(model.state_dict(), model_file)
print('Best model so far, saving...')
print('Epoch: {:04d}'.format(epoch),
'nll_train: {:.10f}'.format(np.mean(loss_train)),
'mse_train: {:.12f}'.format(np.mean(mse_train)),
'mse_baseline_train: {:.10f}'.format(np.mean(mse_baseline_train)),
'nll_val: {:.10f}'.format(np.mean(loss_val)),
'mse_val: {:.12f}'.format(np.mean(mse_val)),
'mse_baseline_val: {:.10f}'.format(np.mean(mse_baseline_val)),
'time: {:.4f}s'.format(time.time() - t), file=log)
log.flush()
return np.mean(loss_val)
def test():
loss_test = []
mse_baseline_test = []
mse_test = []
tot_mse = 0
tot_mse_baseline = 0
counter = 0
model.eval()
model.load_state_dict(torch.load(model_file))
for batch_idx, (inputs, relations) in enumerate(test_loader):
assert (inputs.size(2) - args.timesteps) >= args.timesteps
if args.cuda:
inputs = inputs.cuda()
else:
inputs = inputs.contiguous()
inputs = Variable(inputs, volatile=True)
ins_cut = inputs[:, :, -args.timesteps:, :].contiguous()
output = model(ins_cut, 1)
target = ins_cut[:, :, 1:, :]
loss = nll_gaussian(output, target, args.var)
mse = F.mse_loss(output, target)
mse_baseline = F.mse_loss(ins_cut[:, :, :-1, :], ins_cut[:, :, 1:, :])
loss_test.append(loss.data[0])
mse_test.append(mse.data[0])
mse_baseline_test.append(mse_baseline.data[0])
if args.motion or args.non_markov:
# RNN decoder evaluation setting
# For plotting purposes
output = model(inputs, 100, burn_in=True,
burn_in_steps=args.timesteps)
output = output[:, :, args.timesteps:, :]
target = inputs[:, :, -args.timesteps:, :]
mse = ((target - output) ** 2).mean(dim=0).mean(dim=0).mean(dim=-1)
tot_mse += mse.data.cpu().numpy()
counter += 1
# Baseline over multiple steps
baseline = inputs[:, :, -(args.timesteps + 1):-args.timesteps,
:].expand_as(
target)
mse_baseline = ((target - baseline) ** 2).mean(dim=0).mean(
dim=0).mean(
dim=-1)
tot_mse_baseline += mse_baseline.data.cpu().numpy()
else:
# For plotting purposes
output = model(inputs, 100, burn_in=True,
burn_in_steps=args.timesteps)
output = output[:, :, args.timesteps:args.timesteps + 20, :]
target = inputs[:, :, args.timesteps + 1:args.timesteps + 21, :]
mse = ((target - output) ** 2).mean(dim=0).mean(dim=0).mean(dim=-1)
tot_mse += mse.data.cpu().numpy()
counter += 1
# Baseline over multiple steps
baseline = inputs[:, :, args.timesteps:args.timesteps + 1,
:].expand_as(
target)
mse_baseline = ((target - baseline) ** 2).mean(dim=0).mean(
dim=0).mean(
dim=-1)
tot_mse_baseline += mse_baseline.data.cpu().numpy()
mean_mse = tot_mse / counter
mse_str = '['
for mse_step in mean_mse[:-1]:
mse_str += " {:.12f} ,".format(mse_step)
mse_str += " {:.12f} ".format(mean_mse[-1])
mse_str += ']'
mean_mse_baseline = tot_mse_baseline / counter
mse_baseline_str = '['
for mse_step in mean_mse_baseline[:-1]:
mse_baseline_str += " {:.12f} ,".format(mse_step)
mse_baseline_str += " {:.12f} ".format(mean_mse_baseline[-1])
mse_baseline_str += ']'
print('--------------------------------')
print('--------Testing-----------------')
print('--------------------------------')
print('nll_test: {:.10f}'.format(np.mean(loss_test)),
'mse_test: {:.12f}'.format(np.mean(mse_test)),
'mse_baseline_test: {:.10f}'.format(np.mean(mse_baseline_test)))
print('MSE: {}'.format(mse_str))
print('MSE Baseline: {}'.format(mse_baseline_str))
if args.save_folder:
print('--------------------------------', file=log)
print('--------Testing-----------------', file=log)
print('--------------------------------', file=log)
print('nll_test: {:.10f}'.format(np.mean(loss_test)),
'mse_test: {:.12f}'.format(np.mean(mse_test)),
'mse_baseline_test: {:.10f}'.format(np.mean(mse_baseline_test)),
file=log)
print('MSE: {}'.format(mse_str), file=log)
print('MSE Baseline: {}'.format(mse_baseline_str), file=log)
log.flush()
# Train model
t_total = time.time()
best_val_loss = np.inf
best_epoch = 0
for epoch in range(args.epochs):
val_loss = train(epoch, best_val_loss)
if val_loss < best_val_loss:
best_val_loss = val_loss
best_epoch = epoch
print("Optimization Finished!")
print("Best Epoch: {:04d}".format(best_epoch))
if args.save_folder:
print("Best Epoch: {:04d}".format(best_epoch), file=log)
log.flush()
test()
if log is not None:
print(save_folder)
log.close()