def get_ckpt_model_and_data(args):
# Load checkpoint.
checkpt = torch.load(args.checkpt,
map_location=lambda storage, loc: storage)
ckpt_args = checkpt['args']
state_dict = checkpt['state_dict']
# Construct model and restore checkpoint.
regularization_fns, regularization_coeffs = create_regularization_fns(
ckpt_args)
model = build_model_tabular(ckpt_args, 2,
regularization_fns).to(device)
if ckpt_args.spectral_norm: add_spectral_norm(model)
set_cnf_options(ckpt_args, model)
model.load_state_dict(state_dict)
model.to(device)
print(model)
print("Number of trainable parameters: {}".format(
count_parameters(model)))
# Load samples from dataset
data_samples = toy_data.inf_train_gen(ckpt_args.data, batch_size=2000)
return model, data_samples
z, change = model(x, zero)
logpx = standard_normal_logprob(z).sum(1, keepdim=True) - change
loss = -torch.mean(logpx)
return loss
if __name__ == '__main__':
regularization_fns, regularization_coeffs = create_regularization_fns(args)
model = build_model_tabular(args, 2, regularization_fns).to(device)
if args.spectral_norm: add_spectral_norm(model)
set_cnf_options(args, model)
logger.info(model)
logger.info("Number of trainable parameters: {}".format(count_parameters(model)))
optimizer = optim.Adam(model.parameters(), lr=args.lr, weight_decay=args.weight_decay)
time_meter = utils.RunningAverageMeter(0.93)
loss_meter = utils.RunningAverageMeter(0.93)
nfef_meter = utils.RunningAverageMeter(0.93)
nfeb_meter = utils.RunningAverageMeter(0.93)
tt_meter = utils.RunningAverageMeter(0.93)
end = time.time()
best_loss = float('inf')
model.train()
for itr in range(1, args.niters + 1):
optimizer.zero_grad()
if args.spectral_norm: spectral_norm_power_iteration(model, 1)
def main():
# os.system('shutdown -c') # cancel previous shutdown command
if write_log:
utils.makedirs(args.save)
logger = utils.get_logger(logpath=os.path.join(args.save, 'logs'), filepath=os.path.abspath(__file__))
logger.info(args)
args_file_path = os.path.join(args.save, 'args.yaml')
with open(args_file_path, 'w') as f:
yaml.dump(vars(args), f, default_flow_style=False)
if args.distributed:
if write_log: logger.info('Distributed initializing process group')
torch.cuda.set_device(args.local_rank)
distributed.init_process_group(backend=args.dist_backend, init_method=args.dist_url,
world_size=dist_utils.env_world_size(), rank=env_rank())
assert (dist_utils.env_world_size() == distributed.get_world_size())
if write_log: logger.info("Distributed: success (%d/%d)" % (args.local_rank, distributed.get_world_size()))
device = torch.device("cuda:%d" % torch.cuda.current_device() if torch.cuda.is_available() else "cpu")
else:
device = torch.cuda.current_device() #
# import pdb; pdb.set_trace()
cvt = lambda x: x.type(torch.float32).to(device, non_blocking=True)
# load dataset
train_loader, test_loader, data_shape = get_dataset(args)
trainlog = os.path.join(args.save, 'training.csv')
testlog = os.path.join(args.save, 'test.csv')
traincolumns = ['itr', 'wall', 'itr_time', 'loss', 'bpd', 'fe', 'total_time', 'grad_norm']
testcolumns = ['wall', 'epoch', 'eval_time', 'bpd', 'fe', 'total_time', 'transport_cost']
# build model
regularization_fns, regularization_coeffs = create_regularization_fns(args)
model = create_model(args, data_shape, regularization_fns).cuda()
if args.distributed: model = dist_utils.DDP(model,
device_ids=[args.local_rank],
output_device=args.local_rank)
traincolumns = append_regularization_keys_header(traincolumns, regularization_fns)
if not args.resume and write_log:
with open(trainlog, 'w') as f:
csvlogger = csv.DictWriter(f, traincolumns)
csvlogger.writeheader()
with open(testlog, 'w') as f:
csvlogger = csv.DictWriter(f, testcolumns)
csvlogger.writeheader()
set_cnf_options(args, model)
if write_log: logger.info(model)
if write_log: logger.info("Number of trainable parameters: {}".format(count_parameters(model)))
if write_log: logger.info('Iters per train epoch: {}'.format(len(train_loader)))
if write_log: logger.info('Iters per test: {}'.format(len(test_loader)))
# optimizer
if args.optimizer == 'adam':
optimizer = optim.Adam(model.parameters(), lr=args.lr, weight_decay=args.weight_decay)
elif args.optimizer == 'sgd':
optimizer = optim.SGD(model.parameters(), lr=args.lr, weight_decay=args.weight_decay, momentum=0.9,
nesterov=False)
# restore parameters
# import pdb; pdb.set_trace()
if args.resume is not None:
# import pdb; pdb.set_trace()
print('resume from checkpoint')
checkpt = torch.load(args.resume, map_location=lambda storage, loc: storage.cuda(args.local_rank))
model.load_state_dict(checkpt["state_dict"])
if "optim_state_dict" in checkpt.keys():
optimizer.load_state_dict(checkpt["optim_state_dict"])
# Manually move optimizer state to device.
for state in optimizer.state.values():
for k, v in state.items():
if torch.is_tensor(v):
state[k] = cvt(v)
# For visualization.
if write_log: fixed_z = cvt(torch.randn(min(args.test_batch_size, 100), *data_shape))
if write_log:
time_meter = utils.RunningAverageMeter(0.97)
bpd_meter = utils.RunningAverageMeter(0.97)
loss_meter = utils.RunningAverageMeter(0.97)
steps_meter = utils.RunningAverageMeter(0.97)
grad_meter = utils.RunningAverageMeter(0.97)
tt_meter = utils.RunningAverageMeter(0.97)
if not args.resume:
best_loss = float("inf")
itr = 0
wall_clock = 0.
begin_epoch = 1
chkdir = args.save
'''
elif args.resume and args.validate:
chkdir = os.path.dirname(args.resume)
wall_clock = 0
itr = 0
best_loss = 0.0
begin_epoch = 0
'''
else:
chkdir = os.path.dirname(args.resume)
filename = os.path.join(chkdir, 'test.csv')
print(filename)
tedf = pd.read_csv(os.path.join(chkdir, 'test.csv'))
trdf = pd.read_csv(os.path.join(chkdir, 'training.csv'))
# import pdb; pdb.set_trace()
wall_clock = trdf['wall'].to_numpy()[-1]
itr = trdf['itr'].to_numpy()[-1]
best_loss = tedf['bpd'].min()
begin_epoch = int(tedf['epoch'].to_numpy()[-1] + 1) # not exactly correct
if args.distributed:
if write_log: logger.info('Syncing machines before training')
dist_utils.sum_tensor(torch.tensor([1.0]).float().cuda())
for epoch in range(begin_epoch, begin_epoch + 1):
# compute test loss
print('Evaluating')
model.eval()
if args.local_rank == 0:
utils.makedirs(args.save)
# import pdb; pdb.set_trace()
if hasattr(model, 'module'):
_state = model.module.state_dict()
else:
_state = model.state_dict()
torch.save({
"args": args,
"state_dict": _state, # model.module.state_dict() if torch.cuda.is_available() else model.state_dict(),
"optim_state_dict": optimizer.state_dict(),
"fixed_z": fixed_z.cpu()
}, os.path.join(args.save, "checkpt_%d.pth" % epoch))
# save real and generate with different temperatures
fig_num = 64
if True: # args.save_real:
for i, (x, y) in enumerate(test_loader):
if i < 100:
pass
elif i == 100:
real = x.size(0)
else:
break
if x.shape[0] > fig_num:
x = x[:fig_num, ...]
# import pdb; pdb.set_trace()
fig_filename = os.path.join(chkdir, "real.jpg")
save_image(x.float() / 255.0, fig_filename, nrow=8)
if True: # args.generate:
print('\nGenerating images... ')
fixed_z = cvt(torch.randn(fig_num, *data_shape))
nb = int(np.ceil(np.sqrt(float(fixed_z.size(0)))))
for t in [ 1.0, 0.99, 0.98, 0.97,0.96,0.95,0.93,0.92,0.90,0.85,0.8,0.75,0.7,0.65,0.6]:
# visualize samples and density
fig_filename = os.path.join(chkdir, "generated-T%g.jpg" % t)
utils.makedirs(os.path.dirname(fig_filename))
generated_samples = model(t * fixed_z, reverse=True)
x = unshift(generated_samples[0].view(-1, *data_shape), 8)
save_image(x, fig_filename, nrow=nb)
logger.info(k)
if args.resume is not None:
checkpt = torch.load(args.resume)
# Backwards compatibility with an older version of the code.
# TODO: remove upon release.
filtered_state_dict = {}
for k, v in checkpt['state_dict'].items():
if 'diffeq.diffeq' not in k:
filtered_state_dict[k.replace('module.', '')] = v
model.load_state_dict(filtered_state_dict)
logger.info(model)
logger.info("Number of trainable parameters: {}".format(
count_parameters(model)))
if not args.evaluate:
optimizer = Adam(model.parameters(),
lr=args.lr,
weight_decay=args.weight_decay)
time_meter = utils.RunningAverageMeter(0.98)
loss_meter = utils.RunningAverageMeter(0.98)
nfef_meter = utils.RunningAverageMeter(0.98)
nfeb_meter = utils.RunningAverageMeter(0.98)
tt_meter = utils.RunningAverageMeter(0.98)
best_loss = float('inf')
itr = 0
n_vals_without_improvement = 0
for k in model.state_dict().keys():
logger.info(k)
if args.resume is not None:
logger.info('Training has finished.')
model = restore_model(model, args.resume).to(device)
set_cnf_options(args, model)
else:
logger.info(
'must use --resume flag to provide the state_dict to evaluate')
exit(1)
logger.info(model)
nWeights = count_parameters(model)
logger.info("Number of trainable parameters: {}".format(nWeights))
logger.info('Evaluating model on test set.')
model.eval()
override_divergence_fn(model, "brute_force")
bInverse = True # check one batch for inverse error, for speed
with torch.no_grad():
test_loss = utils.AverageMeter()
test_nfe = utils.AverageMeter()
for itr, x in enumerate(
batch_iter(data.tst.x, batch_size=test_batch_size)):
x = cvt(x)
def train():
model = build_model_tabular(args, 1).to(device)
set_cnf_options(args, model)
logger.info(model)
logger.info("Number of trainable parameters: {}".format(
count_parameters(model)))
optimizer = optim.Adam(model.parameters(),
lr=args.lr,
weight_decay=args.weight_decay)
time_meter = utils.RunningAverageMeter(0.93)
loss_meter = utils.RunningAverageMeter(0.93)
nfef_meter = utils.RunningAverageMeter(0.93)
nfeb_meter = utils.RunningAverageMeter(0.93)
tt_meter = utils.RunningAverageMeter(0.93)
end = time.time()
best_loss = float('inf')
model.train()
for itr in range(1, args.niters + 1):
optimizer.zero_grad()
loss = compute_loss(args, model)
loss_meter.update(loss.item())
total_time = count_total_time(model)
nfe_forward = count_nfe(model)
loss.backward()
optimizer.step()
nfe_total = count_nfe(model)
nfe_backward = nfe_total - nfe_forward
nfef_meter.update(nfe_forward)
nfeb_meter.update(nfe_backward)
time_meter.update(time.time() - end)
tt_meter.update(total_time)
log_message = (
'Iter {:04d} | Time {:.4f}({:.4f}) | Loss {:.6f}({:.6f}) | NFE Forward {:.0f}({:.1f})'
' | NFE Backward {:.0f}({:.1f}) | CNF Time {:.4f}({:.4f})'.format(
itr, time_meter.val, time_meter.avg, loss_meter.val,
loss_meter.avg, nfef_meter.val, nfef_meter.avg, nfeb_meter.val,
nfeb_meter.avg, tt_meter.val, tt_meter.avg))
logger.info(log_message)
if itr % args.val_freq == 0 or itr == args.niters:
with torch.no_grad():
model.eval()
test_loss = compute_loss(args,
model,
batch_size=args.test_batch_size)
test_nfe = count_nfe(model)
log_message = '[TEST] Iter {:04d} | Test Loss {:.6f} | NFE {:.0f}'.format(
itr, test_loss, test_nfe)
logger.info(log_message)
if test_loss.item() < best_loss:
best_loss = test_loss.item()
utils.makedirs(args.save)
torch.save(
{
'args': args,
'state_dict': model.state_dict(),
}, os.path.join(args.save, 'checkpt.pth'))
model.train()
if itr % args.viz_freq == 0:
with torch.no_grad():
model.eval()
xx = torch.linspace(-10, 10, 10000).view(-1, 1)
true_p = data_density(xx)
plt.plot(xx.view(-1).cpu().numpy(),
true_p.view(-1).exp().cpu().numpy(),
label='True')
true_p = model_density(xx, model)
plt.plot(xx.view(-1).cpu().numpy(),
true_p.view(-1).exp().cpu().numpy(),
label='Model')
utils.makedirs(os.path.join(args.save, 'figs'))
plt.savefig(
os.path.join(args.save, 'figs', '{:06d}.jpg'.format(itr)))
plt.close()
model.train()
end = time.time()
logger.info('Training has finished.')
def main():
#os.system('shutdown -c') # cancel previous shutdown command
if write_log:
utils.makedirs(args.save)
logger = utils.get_logger(logpath=os.path.join(args.save, 'logs'),
filepath=os.path.abspath(__file__))
logger.info(args)
args_file_path = os.path.join(args.save, 'args.yaml')
with open(args_file_path, 'w') as f:
yaml.dump(vars(args), f, default_flow_style=False)
if args.distributed:
if write_log: logger.info('Distributed initializing process group')
torch.cuda.set_device(args.local_rank)
distributed.init_process_group(backend=args.dist_backend,
init_method=args.dist_url,
world_size=dist_utils.env_world_size(),
rank=env_rank())
assert (dist_utils.env_world_size() == distributed.get_world_size())
if write_log:
logger.info("Distributed: success (%d/%d)" %
(args.local_rank, distributed.get_world_size()))
# get deivce
# device = torch.device("cuda:%d"%torch.cuda.current_device() if torch.cuda.is_available() else "cpu")
device = "cpu"
cvt = lambda x: x.type(torch.float32).to(device, non_blocking=True)
# load dataset
train_loader, test_loader, data_shape = get_dataset(args)
trainlog = os.path.join(args.save, 'training.csv')
testlog = os.path.join(args.save, 'test.csv')
traincolumns = [
'itr', 'wall', 'itr_time', 'loss', 'bpd', 'fe', 'total_time',
'grad_norm'
]
testcolumns = [
'wall', 'epoch', 'eval_time', 'bpd', 'fe', 'total_time',
'transport_cost'
]
# build model
regularization_fns, regularization_coeffs = create_regularization_fns(args)
model = create_model(args, data_shape, regularization_fns)
# model = model.cuda()
if args.distributed:
model = dist_utils.DDP(model,
device_ids=[args.local_rank],
output_device=args.local_rank)
traincolumns = append_regularization_keys_header(traincolumns,
regularization_fns)
if not args.resume and write_log:
with open(trainlog, 'w') as f:
csvlogger = csv.DictWriter(f, traincolumns)
csvlogger.writeheader()
with open(testlog, 'w') as f:
csvlogger = csv.DictWriter(f, testcolumns)
csvlogger.writeheader()
set_cnf_options(args, model)
if write_log: logger.info(model)
if write_log:
logger.info("Number of trainable parameters: {}".format(
count_parameters(model)))
if write_log:
logger.info('Iters per train epoch: {}'.format(len(train_loader)))
if write_log: logger.info('Iters per test: {}'.format(len(test_loader)))
# optimizer
if args.optimizer == 'adam':
optimizer = optim.Adam(model.parameters(),
lr=args.lr,
weight_decay=args.weight_decay)
elif args.optimizer == 'sgd':
optimizer = optim.SGD(model.parameters(),
lr=args.lr,
weight_decay=args.weight_decay,
momentum=0.9,
nesterov=False)
# restore parameters
if args.resume is not None:
checkpt = torch.load(
args.resume,
map_location=lambda storage, loc: storage.cuda(args.local_rank))
model.load_state_dict(checkpt["state_dict"])
if "optim_state_dict" in checkpt.keys():
optimizer.load_state_dict(checkpt["optim_state_dict"])
# Manually move optimizer state to device.
for state in optimizer.state.values():
for k, v in state.items():
if torch.is_tensor(v):
state[k] = cvt(v)
# For visualization.
if write_log:
fixed_z = cvt(torch.randn(min(args.test_batch_size, 100), *data_shape))
if write_log:
time_meter = utils.RunningAverageMeter(0.97)
bpd_meter = utils.RunningAverageMeter(0.97)
loss_meter = utils.RunningAverageMeter(0.97)
steps_meter = utils.RunningAverageMeter(0.97)
grad_meter = utils.RunningAverageMeter(0.97)
tt_meter = utils.RunningAverageMeter(0.97)
if not args.resume:
best_loss = float("inf")
itr = 0
wall_clock = 0.
begin_epoch = 1
else:
chkdir = os.path.dirname(args.resume)
tedf = pd.read_csv(os.path.join(chkdir, 'test.csv'))
trdf = pd.read_csv(os.path.join(chkdir, 'training.csv'))
wall_clock = trdf['wall'].to_numpy()[-1]
itr = trdf['itr'].to_numpy()[-1]
best_loss = tedf['bpd'].min()
begin_epoch = int(tedf['epoch'].to_numpy()[-1] +
1) # not exactly correct
if args.distributed:
if write_log: logger.info('Syncing machines before training')
dist_utils.sum_tensor(torch.tensor([1.0]).float().cuda())
for epoch in range(begin_epoch, args.num_epochs + 1):
if not args.validate:
model.train()
with open(trainlog, 'a') as f:
if write_log: csvlogger = csv.DictWriter(f, traincolumns)
for _, (x, y) in enumerate(train_loader):
start = time.time()
update_lr(optimizer, itr)
optimizer.zero_grad()
# cast data and move to device
x = add_noise(cvt(x), nbits=args.nbits)
#x = x.clamp_(min=0, max=1)
# compute loss
bpd, (x, z), reg_states = compute_bits_per_dim(x, model)
if np.isnan(bpd.data.item()):
raise ValueError('model returned nan during training')
elif np.isinf(bpd.data.item()):
raise ValueError('model returned inf during training')
loss = bpd
if regularization_coeffs:
reg_loss = sum(reg_state * coeff
for reg_state, coeff in zip(
reg_states, regularization_coeffs)
if coeff != 0)
loss = loss + reg_loss
total_time = count_total_time(model)
loss.backward()
nfe_opt = count_nfe(model)
if write_log: steps_meter.update(nfe_opt)
grad_norm = torch.nn.utils.clip_grad_norm_(
model.parameters(), args.max_grad_norm)
optimizer.step()
itr_time = time.time() - start
wall_clock += itr_time
batch_size = x.size(0)
metrics = torch.tensor([
1., batch_size,
loss.item(),
bpd.item(), nfe_opt, grad_norm, *reg_states
]).float()
rv = tuple(torch.tensor(0.) for r in reg_states)
total_gpus, batch_total, r_loss, r_bpd, r_nfe, r_grad_norm, *rv = dist_utils.sum_tensor(
metrics).cpu().numpy()
if write_log:
time_meter.update(itr_time)
bpd_meter.update(r_bpd / total_gpus)
loss_meter.update(r_loss / total_gpus)
grad_meter.update(r_grad_norm / total_gpus)
tt_meter.update(total_time)
fmt = '{:.4f}'
logdict = {
'itr': itr,
'wall': fmt.format(wall_clock),
'itr_time': fmt.format(itr_time),
'loss': fmt.format(r_loss / total_gpus),
'bpd': fmt.format(r_bpd / total_gpus),
'total_time': fmt.format(total_time),
'fe': r_nfe / total_gpus,
'grad_norm': fmt.format(r_grad_norm / total_gpus),
}
if regularization_coeffs:
rv = tuple(v_ / total_gpus for v_ in rv)
logdict = append_regularization_csv_dict(
logdict, regularization_fns, rv)
csvlogger.writerow(logdict)
if itr % args.log_freq == 0:
log_message = (
"Itr {:06d} | Wall {:.3e}({:.2f}) | "
"Time/Itr {:.2f}({:.2f}) | BPD {:.2f}({:.2f}) | "
"Loss {:.2f}({:.2f}) | "
"FE {:.0f}({:.0f}) | Grad Norm {:.3e}({:.3e}) | "
"TT {:.2f}({:.2f})".format(
itr, wall_clock, wall_clock / (itr + 1),
time_meter.val, time_meter.avg,
bpd_meter.val, bpd_meter.avg,
loss_meter.val, loss_meter.avg,
steps_meter.val, steps_meter.avg,
grad_meter.val, grad_meter.avg,
tt_meter.val, tt_meter.avg))
if regularization_coeffs:
log_message = append_regularization_to_log(
log_message, regularization_fns, rv)
logger.info(log_message)
itr += 1
# compute test loss
model.eval()
if args.local_rank == 0:
utils.makedirs(args.save)
torch.save(
{
"args":
args,
"state_dict":
model.module.state_dict()
if torch.cuda.is_available() else model.state_dict(),
"optim_state_dict":
optimizer.state_dict(),
"fixed_z":
fixed_z.cpu()
}, os.path.join(args.save, "checkpt.pth"))
if epoch % args.val_freq == 0 or args.validate:
with open(testlog, 'a') as f:
if write_log: csvlogger = csv.DictWriter(f, testcolumns)
with torch.no_grad():
start = time.time()
if write_log: logger.info("validating...")
lossmean = 0.
meandist = 0.
steps = 0
tt = 0.
for i, (x, y) in enumerate(test_loader):
sh = x.shape
x = shift(cvt(x), nbits=args.nbits)
loss, (x, z), _ = compute_bits_per_dim(x, model)
dist = (x.view(x.size(0), -1) -
z).pow(2).mean(dim=-1).mean()
meandist = i / (i + 1) * dist + meandist / (i + 1)
lossmean = i / (i + 1) * lossmean + loss / (i + 1)
tt = i / (i + 1) * tt + count_total_time(model) / (i +
1)
steps = i / (i + 1) * steps + count_nfe(model) / (i +
1)
loss = lossmean.item()
metrics = torch.tensor([1., loss, meandist, steps]).float()
total_gpus, r_bpd, r_mdist, r_steps = dist_utils.sum_tensor(
metrics).cpu().numpy()
eval_time = time.time() - start
if write_log:
fmt = '{:.4f}'
logdict = {
'epoch': epoch,
'eval_time': fmt.format(eval_time),
'bpd': fmt.format(r_bpd / total_gpus),
'wall': fmt.format(wall_clock),
'total_time': fmt.format(tt),
'transport_cost': fmt.format(r_mdist / total_gpus),
'fe': '{:.2f}'.format(r_steps / total_gpus)
}
csvlogger.writerow(logdict)
logger.info(
"Epoch {:04d} | Time {:.4f}, Bit/dim {:.4f}, Steps {:.4f}, TT {:.2f}, Transport Cost {:.2e}"
.format(epoch, eval_time, r_bpd / total_gpus,
r_steps / total_gpus, tt,
r_mdist / total_gpus))
loss = r_bpd / total_gpus
if loss < best_loss and args.local_rank == 0:
best_loss = loss
shutil.copyfile(os.path.join(args.save, "checkpt.pth"),
os.path.join(args.save, "best.pth"))
# visualize samples and density
if write_log:
with torch.no_grad():
fig_filename = os.path.join(args.save, "figs",
"{:04d}.jpg".format(epoch))
utils.makedirs(os.path.dirname(fig_filename))
generated_samples, _, _ = model(fixed_z, reverse=True)
generated_samples = generated_samples.view(-1, *data_shape)
nb = int(np.ceil(np.sqrt(float(fixed_z.size(0)))))
save_image(unshift(generated_samples, nbits=args.nbits),
fig_filename,
nrow=nb)
if args.validate:
break
if __name__ == '__main__':
if args.discrete:
model = construct_discrete_model().to(device)
model.load_state_dict(torch.load(args.checkpt)['state_dict'])
else:
model = build_model_tabular(args, 2).to(device)
sd = torch.load(args.checkpt)['state_dict']
fixed_sd = {}
for k, v in sd.items():
fixed_sd[k.replace('odefunc.odefunc', 'odefunc')] = v
model.load_state_dict(fixed_sd)
print(model)
print("Number of trainable parameters: {}".format(count_parameters(model)))
model.eval()
p_samples = toy_data.inf_train_gen(args.data, batch_size=800**2)
with torch.no_grad():
sample_fn, density_fn = get_transforms(model)
plt.figure(figsize=(10, 10))
ax = ax = plt.gca()
viz_flow.plt_samples(p_samples, ax, npts=800)
plt.subplots_adjust(left=0, right=1, top=1, bottom=0)
fig_filename = os.path.join(args.save, 'figs', 'true_samples.jpg')
utils.makedirs(os.path.dirname(fig_filename))
plt.savefig(fig_filename)
plt.close()
train_loader, val_loader = get_dataset(args)
# build model
regularization_fns, regularization_coeffs = create_regularization_fns(args)
aug_model = build_augmented_model_tabular(
args,
args.aug_size + args.effective_shape,
regularization_fns=regularization_fns,
)
set_cnf_options(args, aug_model)
logger.info(aug_model)
logger.info("Number of trainable parameters: {}".format(
count_parameters(aug_model)))
# optimizer
parameter_list = list(aug_model.parameters())
optimizer, num_params = optimizer_factory(args, parameter_list)
print("Num of Parameters: %d" % num_params)
# restore parameters
itr = 0
if args.resume is not None:
checkpt = torch.load(args.resume,
map_location=lambda storage, loc: storage)
aug_model.load_state_dict(checkpt["state_dict"])
if "optim_state_dict" in checkpt.keys():
optimizer.load_state_dict(checkpt["optim_state_dict"])
# Manually move optimizer state to device.
def run(args, kwargs):
# ==================================================================================================================
# SNAPSHOTS
# ==================================================================================================================
args.model_signature = str(datetime.datetime.now())[0:19].replace(' ', '_')
args.model_signature = args.model_signature.replace(':', '_')
if args.automatic_saving == True:
path = '{}/{}/{}/{}/{}/{}/{}/{}/{}/'.format(args.solver, args.dataset,
args.layer_type, args.atol,
args.rtol, args.atol_start,
args.rtol_start,
args.warmup_steps,
args.manual_seed)
else:
path = 'test/'
args.snap_dir = os.path.join(args.out_dir, path)
if not os.path.exists(args.snap_dir):
os.makedirs(args.snap_dir)
# logger
utils.makedirs(args.snap_dir)
logger = utils.get_logger(logpath=os.path.join(args.snap_dir, 'logs'),
filepath=os.path.abspath(__file__))
logger.info(args)
# SAVING
torch.save(args, args.snap_dir + 'config.config')
# ==================================================================================================================
# LOAD DATA
# ==================================================================================================================
train_loader, val_loader, test_loader, args = load_dataset(args, **kwargs)
if not args.evaluate:
nfef_meter = utils.AverageMeter()
nfeb_meter = utils.AverageMeter()
# ==============================================================================================================
# SELECT MODEL
# ==============================================================================================================
# flow parameters and architecture choice are passed on to model through args
if args.flow == 'no_flow':
model = VAE.VAE(args)
elif args.flow == 'planar':
model = VAE.PlanarVAE(args)
elif args.flow == 'iaf':
model = VAE.IAFVAE(args)
elif args.flow == 'orthogonal':
model = VAE.OrthogonalSylvesterVAE(args)
elif args.flow == 'householder':
model = VAE.HouseholderSylvesterVAE(args)
elif args.flow == 'triangular':
model = VAE.TriangularSylvesterVAE(args)
elif args.flow == 'cnf':
model = CNFVAE.CNFVAE(args)
elif args.flow == 'cnf_bias':
model = CNFVAE.AmortizedBiasCNFVAE(args)
elif args.flow == 'cnf_hyper':
model = CNFVAE.HypernetCNFVAE(args)
elif args.flow == 'cnf_lyper':
model = CNFVAE.LypernetCNFVAE(args)
elif args.flow == 'cnf_rank':
model = CNFVAE.AmortizedLowRankCNFVAE(args)
else:
raise ValueError('Invalid flow choice')
if args.retrain_encoder:
logger.info(f"Initializing decoder from {args.model_path}")
dec_model = torch.load(args.model_path)
dec_sd = {}
for k, v in dec_model.state_dict().items():
if 'p_x' in k:
dec_sd[k] = v
model.load_state_dict(dec_sd, strict=False)
if args.cuda:
logger.info("Model on GPU")
model.cuda()
logger.info(model)
logger.info("Number of trainable parameters: {}".format(
count_parameters(model)))
if args.retrain_encoder:
parameters = []
logger.info('Optimizing over:')
for name, param in model.named_parameters():
if 'p_x' not in name:
logger.info(name)
parameters.append(param)
else:
parameters = model.parameters()
optimizer = optim.Adamax(parameters, lr=args.learning_rate, eps=1.e-7)
# ==================================================================================================================
# TRAINING
# ==================================================================================================================
train_loss = []
val_loss = []
# for early stopping
best_loss = np.inf
best_bpd = np.inf
e = 0
epoch = 0
train_times = []
for epoch in range(1, args.epochs + 1):
atol, rtol = update_tolerances(args, epoch, decay_factors)
print(atol)
set_cnf_options(args, atol, rtol, model)
t_start = time.time()
if 'cnf' not in args.flow:
tr_loss = train(epoch, train_loader, model, optimizer, args,
logger)
else:
tr_loss, nfef_meter, nfeb_meter = train(
epoch, train_loader, model, optimizer, args, logger,
nfef_meter, nfeb_meter)
train_loss.append(tr_loss)
train_times.append(time.time() - t_start)
logger.info('One training epoch took %.2f seconds' %
(time.time() - t_start))
v_loss, v_bpd = evaluate(val_loader,
model,
args,
logger,
epoch=epoch)
val_loss.append(v_loss)
# early-stopping
if v_loss < best_loss:
e = 0
best_loss = v_loss
if args.input_type != 'binary':
best_bpd = v_bpd
logger.info('->model saved<-')
torch.save(model, args.snap_dir + 'model.model')
# torch.save(model, snap_dir + args.flow + '_' + args.architecture + '.model')
elif (args.early_stopping_epochs > 0) and (epoch >= args.warmup):
e += 1
if e > args.early_stopping_epochs:
break
if args.input_type == 'binary':
logger.info(
'--> Early stopping: {}/{} (BEST: loss {:.4f})\n'.format(
e, args.early_stopping_epochs, best_loss))
else:
logger.info(
'--> Early stopping: {}/{} (BEST: loss {:.4f}, bpd {:.4f})\n'
.format(e, args.early_stopping_epochs, best_loss,
best_bpd))
if math.isnan(v_loss):
raise ValueError('NaN encountered!')
train_loss = np.hstack(train_loss)
val_loss = np.array(val_loss)
plot_training_curve(train_loss,
val_loss,
fname=args.snap_dir + '/training_curve.pdf')
# training time per epoch
train_times = np.array(train_times)
mean_train_time = np.mean(train_times)
std_train_time = np.std(train_times, ddof=1)
logger.info('Average train time per epoch: %.2f +/- %.2f' %
(mean_train_time, std_train_time))
# ==================================================================================================================
# EVALUATION
# ==================================================================================================================
logger.info(args)
logger.info('Stopped after %d epochs' % epoch)
logger.info('Average train time per epoch: %.2f +/- %.2f' %
(mean_train_time, std_train_time))
final_model = torch.load(args.snap_dir + 'model.model')
validation_loss, validation_bpd = evaluate(val_loader, final_model,
args, logger)
else:
validation_loss = "N/A"
validation_bpd = "N/A"
logger.info(f"Loading model from {args.model_path}")
final_model = torch.load(args.model_path)
test_loss, test_bpd = evaluate(test_loader,
final_model,
args,
logger,
testing=True)
logger.info(
'FINAL EVALUATION ON VALIDATION SET. ELBO (VAL): {:.4f}'.format(
validation_loss))
def train(args, model, growth_model):
logger.info(model)
logger.info("Number of trainable parameters: {}".format(count_parameters(model)))
#optimizer = optim.Adam(set(model.parameters()) | set(growth_model.parameters()),
optimizer = optim.Adam(model.parameters(),
lr=args.lr, weight_decay=args.weight_decay)
#growth_optimizer = optim.Adam(growth_model.parameters(), lr=args.lr, weight_decay=args.weight_decay)
time_meter = utils.RunningAverageMeter(0.93)
loss_meter = utils.RunningAverageMeter(0.93)
nfef_meter = utils.RunningAverageMeter(0.93)
nfeb_meter = utils.RunningAverageMeter(0.93)
tt_meter = utils.RunningAverageMeter(0.93)
end = time.time()
best_loss = float('inf')
model.train()
growth_model.eval()
for itr in range(1, args.niters + 1):
optimizer.zero_grad()
#growth_optimizer.zero_grad()
### Train
if args.spectral_norm: spectral_norm_power_iteration(model, 1)
#if args.spectral_norm: spectral_norm_power_iteration(growth_model, 1)
loss = compute_loss(args, model, growth_model)
loss_meter.update(loss.item())
if len(regularization_coeffs) > 0:
# Only regularize on the last timepoint
reg_states = get_regularization(model, regularization_coeffs)
reg_loss = sum(
reg_state * coeff for reg_state, coeff in zip(reg_states, regularization_coeffs) if coeff != 0
)
loss = loss + reg_loss
#if len(growth_regularization_coeffs) > 0:
# growth_reg_states = get_regularization(growth_model, growth_regularization_coeffs)
# reg_loss = sum(
# reg_state * coeff for reg_state, coeff in zip(growth_reg_states, growth_regularization_coeffs) if coeff != 0
# )
# loss2 = loss2 + reg_loss
total_time = count_total_time(model)
nfe_forward = count_nfe(model)
loss.backward()
#loss2.backward()
optimizer.step()
#growth_optimizer.step()
### Eval
nfe_total = count_nfe(model)
nfe_backward = nfe_total - nfe_forward
nfef_meter.update(nfe_forward)
nfeb_meter.update(nfe_backward)
time_meter.update(time.time() - end)
tt_meter.update(total_time)
log_message = (
'Iter {:04d} | Time {:.4f}({:.4f}) | Loss {:.6f}({:.6f}) | NFE Forward {:.0f}({:.1f})'
' | NFE Backward {:.0f}({:.1f}) | CNF Time {:.4f}({:.4f})'.format(
itr, time_meter.val, time_meter.avg, loss_meter.val, loss_meter.avg, nfef_meter.val, nfef_meter.avg,
nfeb_meter.val, nfeb_meter.avg, tt_meter.val, tt_meter.avg
)
)
if len(regularization_coeffs) > 0:
log_message = append_regularization_to_log(log_message, regularization_fns, reg_states)
logger.info(log_message)
if itr % args.val_freq == 0 or itr == args.niters:
with torch.no_grad():
model.eval()
growth_model.eval()
test_loss = compute_loss(args, model, growth_model)
test_nfe = count_nfe(model)
log_message = '[TEST] Iter {:04d} | Test Loss {:.6f} | NFE {:.0f}'.format(itr, test_loss, test_nfe)
logger.info(log_message)
if test_loss.item() < best_loss:
best_loss = test_loss.item()
utils.makedirs(args.save)
torch.save({
'args': args,
'state_dict': model.state_dict(),
'growth_state_dict': growth_model.state_dict(),
}, os.path.join(args.save, 'checkpt.pth'))
model.train()
if itr % args.viz_freq == 0:
with torch.no_grad():
model.eval()
for i, tp in enumerate(timepoints):
p_samples = viz_sampler(tp)
sample_fn, density_fn = get_transforms(model, int_tps[:i+1])
#growth_sample_fn, growth_density_fn = get_transforms(growth_model, int_tps[:i+1])
plt.figure(figsize=(9, 3))
visualize_transform(
p_samples, torch.randn, standard_normal_logprob, transform=sample_fn, inverse_transform=density_fn,
samples=True, npts=100, device=device
)
fig_filename = os.path.join(args.save, 'figs', '{:04d}_{:01d}.jpg'.format(itr, i))
utils.makedirs(os.path.dirname(fig_filename))
plt.savefig(fig_filename)
plt.close()
#visualize_transform(
# p_samples, torch.rand, uniform_logprob, transform=growth_sample_fn,
# inverse_transform=growth_density_fn,
# samples=True, npts=800, device=device
#)
#fig_filename = os.path.join(args.save, 'growth_figs', '{:04d}_{:01d}.jpg'.format(itr, i))
#utils.makedirs(os.path.dirname(fig_filename))
#plt.savefig(fig_filename)
#plt.close()
model.train()
"""
if itr % args.viz_freq_growth == 0:
with torch.no_grad():
growth_model.eval()
# Visualize growth transform
growth_filename = os.path.join(args.save, 'growth', '{:04d}.jpg'.format(itr))
utils.makedirs(os.path.dirname(growth_filename))
visualize_growth(growth_model, data, labels, npts=200, device=device)
plt.savefig(growth_filename)
plt.close()
growth_model.train()
"""
end = time.time()
logger.info('Training has finished.')
if args.encoder == "ode_rnn":
encoder = create_ode_rnn_encoder(args, device)
else:
raise NotImplementedError
regularization_fns, regularization_coeffs = create_regularization_fns(args)
aug_model = build_augmented_model_tabular(
args,
args.aug_size + args.effective_shape + args.latent_size,
regularization_fns=regularization_fns,
)
set_cnf_options(args, aug_model)
logger.info(aug_model)
logger.info(
"Number of trainable parameters: {}".format(count_parameters(aug_model))
)
# optimizer
optimizer = optim.Adam(
list(aug_model.parameters()) + list(encoder.parameters()),
lr=args.lr,
weight_decay=args.weight_decay,
)
num_params = sum(p.numel() for p in aug_model.parameters() if p.requires_grad)
if args.aggressive:
encoder_optimizer = optim.Adam(
encoder.parameters(), lr=args.lr, weight_decay=args.weight_decay
)
enc_num_params = sum(p.numel() for p in encoder.parameters() if p.requires_grad)
def main(args):
# logger
print(args.no_display_loss)
utils.makedirs(args.save)
logger = utils.get_logger(
logpath=os.path.join(args.save, "logs"),
filepath=os.path.abspath(__file__),
displaying=~args.no_display_loss,
)
if args.layer_type == "blend":
logger.info("!! Setting time_scale from None to 1.0 for Blend layers.")
args.time_scale = 1.0
logger.info(args)
device = torch.device(
"cuda:" + str(args.gpu) if torch.cuda.is_available() else "cpu"
)
if args.use_cpu:
device = torch.device("cpu")
args.data = dataset.SCData.factory(args.dataset, args.max_dim)
args.timepoints = args.data.get_unique_times()
# Use maximum timepoint to establish integration_times
# as some timepoints may be left out for validation etc.
args.int_tps = (np.arange(max(args.timepoints) + 1) + 1.0) * args.time_scale
regularization_fns, regularization_coeffs = create_regularization_fns(args)
model = build_model_tabular(args, args.data.get_shape()[0], regularization_fns).to(
device
)
if args.use_growth:
if args.leaveout_timepoint == -1:
growth_model_path = (
"../data/externel/growth_model_v2.ckpt"
)
elif args.leaveout_timepoint in [1, 2, 3]:
assert args.max_dim == 5
growth_model_path = (
"../data/growth/model_%d"
% args.leaveout_timepoint
)
else:
print("WARNING: Cannot use growth with this timepoint")
growth_model = torch.load(growth_model_path, map_location=device)
if args.spectral_norm:
add_spectral_norm(model)
set_cnf_options(args, model)
if args.test:
state_dict = torch.load(args.save + "/checkpt.pth", map_location=device)
model.load_state_dict(state_dict["state_dict"])
# if "growth_state_dict" not in state_dict:
# print("error growth model note in save")
# growth_model = None
# else:
# checkpt = torch.load(args.save + "/checkpt.pth", map_location=device)
# growth_model.load_state_dict(checkpt["growth_state_dict"])
# TODO can we load the arguments from the save?
# eval_utils.generate_samples(
# device, args, model, growth_model, timepoint=args.leaveout_timepoint
# )
# with torch.no_grad():
# evaluate(device, args, model, growth_model)
# exit()
else:
logger.info(model)
n_param = count_parameters(model)
logger.info("Number of trainable parameters: {}".format(n_param))
train(
device,
args,
model,
growth_model,
regularization_coeffs,
regularization_fns,
logger,
)
if args.data.data.shape[1] == 2:
plot_output(device, args, model)
