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latent_ode.py
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latent_ode.py
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import os
import argparse
import logging
import time
import numpy as np
import numpy.random as npr
import matplotlib
matplotlib.use('agg')
import matplotlib.pyplot as plt
import torch
import torch.nn as nn
import torch.optim as optim
import torch.nn.functional as F
parser = argparse.ArgumentParser()
parser.add_argument('--adjoint', type=eval, default=False)
parser.add_argument('--visualize', type=eval, default=False)
parser.add_argument('--niters', type=int, default=2000)
parser.add_argument('--lr', type=float, default=0.01)
parser.add_argument('--gpu', type=int, default=0)
parser.add_argument('--train_dir', type=str, default=None)
args = parser.parse_args()
if args.adjoint:
from torchdiffeq import odeint_adjoint as odeint
else:
from torchdiffeq import odeint
def generate_spiral2d(nspiral=1000,
ntotal=500,
nsample=100,
start=0.,
stop=1, # approximately equal to 6pi
noise_std=.1,
a=0.,
b=1.,
savefig=True):
"""Parametric formula for 2d spiral is `r = a + b * theta`.
Args:
nspiral: number of spirals, i.e. batch dimension
ntotal: total number of datapoints per spiral
nsample: number of sampled datapoints for model fitting per spiral
start: spiral starting theta value
stop: spiral ending theta value
noise_std: observation noise standard deviation
a, b: parameters of the Archimedean spiral
savefig: plot the ground truth for sanity check
Returns:
Tuple where first element is true trajectory of size (nspiral, ntotal, 2),
second element is noisy observations of size (nspiral, nsample, 2),
third element is timestamps of size (ntotal,),
and fourth element is timestamps of size (nsample,)
"""
# add 1 all timestamps to avoid division by 0
orig_ts = np.linspace(start, stop, num=ntotal)
samp_ts = orig_ts[:nsample]
# generate clock-wise and counter clock-wise spirals in observation space
# with two sets of time-invariant latent dynamics
zs_cw = stop + 1. - orig_ts
rs_cw = a + b * 50. / zs_cw
xs, ys = rs_cw * np.cos(zs_cw) - 5., rs_cw * np.sin(zs_cw)
orig_traj_cw = np.stack((xs, ys), axis=1)
zs_cc = orig_ts
rw_cc = a + b * zs_cc
xs, ys = rw_cc * np.cos(zs_cc) + 5., rw_cc * np.sin(zs_cc)
orig_traj_cc = np.stack((xs, ys), axis=1)
if savefig:
plt.figure()
plt.plot(orig_traj_cw[:, 0], orig_traj_cw[:, 1], label='clock')
plt.plot(orig_traj_cc[:, 0], orig_traj_cc[:, 1], label='counter clock')
plt.legend()
plt.savefig('./ground_truth.png', dpi=500)
print('Saved ground truth spiral at {}'.format('./ground_truth.png'))
# sample starting timestamps
orig_trajs = []
samp_trajs = []
for _ in range(nspiral):
# don't sample t0 very near the start or the end
t0_idx = npr.multinomial(
1, [1. / (ntotal - 2. * nsample)] * (ntotal - int(2 * nsample)))
t0_idx = np.argmax(t0_idx) + nsample
cc = bool(npr.rand() > .5) # uniformly select rotation
orig_traj = orig_traj_cc if cc else orig_traj_cw
orig_trajs.append(orig_traj)
samp_traj = orig_traj[t0_idx:t0_idx + nsample, :].copy()
samp_traj += npr.randn(*samp_traj.shape) * noise_std
samp_trajs.append(samp_traj)
# batching for sample trajectories is good for RNN; batching for original
# trajectories only for ease of indexing
orig_trajs = np.stack(orig_trajs, axis=0)
samp_trajs = np.stack(samp_trajs, axis=0)
return orig_trajs, samp_trajs, orig_ts, samp_ts
class LatentODEfunc(nn.Module):
def __init__(self, latent_dim=4, nhidden=20):
super(LatentODEfunc, self).__init__()
self.elu = nn.ELU(inplace=True)
self.fc1 = nn.Linear(latent_dim, nhidden)
self.fc2 = nn.Linear(nhidden, nhidden)
self.fc3 = nn.Linear(nhidden, latent_dim)
self.nfe = 0
def forward(self, t, x):
self.nfe += 1
out = self.fc1(x)
out = self.elu(out)
out = self.fc2(out)
out = self.elu(out)
out = self.fc3(out)
return out
class RecognitionRNN(nn.Module):
def __init__(self, latent_dim=4, obs_dim=2, nhidden=25, nbatch=1):
super(RecognitionRNN, self).__init__()
self.nhidden = nhidden
self.nbatch = nbatch
self.i2h = nn.Linear(obs_dim + nhidden, nhidden)
self.h2o = nn.Linear(nhidden, latent_dim * 2)
def forward(self, x, h):
combined = torch.cat((x, h), dim=1)
h = torch.tanh(self.i2h(combined))
out = self.h2o(h)
return out, h
def initHidden(self):
return torch.zeros(self.nbatch, self.nhidden)
class Decoder(nn.Module):
def __init__(self, latent_dim=4, obs_dim=2, nhidden=20):
super(Decoder, self).__init__()
self.relu = nn.ReLU(inplace=True)
self.fc1 = nn.Linear(latent_dim, nhidden)
self.fc2 = nn.Linear(nhidden, obs_dim)
def forward(self, z):
out = self.fc1(z)
out = self.relu(out)
out = self.fc2(out)
return out
class RunningAverageMeter(object):
"""Computes and stores the average and current value"""
def __init__(self, momentum=0.99):
self.momentum = momentum
self.reset()
def reset(self):
self.val = None
self.avg = 0
def update(self, val):
if self.val is None:
self.avg = val
else:
self.avg = self.avg * self.momentum + val * (1 - self.momentum)
self.val = val
def log_normal_pdf(x, mean, logvar):
const = torch.from_numpy(np.array([2. * np.pi])).float().to(x.device)
const = torch.log(const)
return -.5 * (const + logvar + (x - mean) ** 2. / torch.exp(logvar))
def normal_kl(mu1, lv1, mu2, lv2):
v1 = torch.exp(lv1)
v2 = torch.exp(lv2)
lstd1 = lv1 / 2.
lstd2 = lv2 / 2.
kl = lstd2 - lstd1 + ((v1 + (mu1 - mu2) ** 2.) / (2. * v2)) - .5
return kl
if __name__ == '__main__':
latent_dim = 4
nhidden = 20
rnn_nhidden = 25
obs_dim = 2
nspiral = 1000
start = 0.
stop = 6 * np.pi
noise_std = .3
a = 0.
b = .3
ntotal = 1000
nsample = 100
device = torch.device('cuda:' + str(args.gpu)
if torch.cuda.is_available() else 'cpu')
# generate toy spiral data
orig_trajs, samp_trajs, orig_ts, samp_ts = generate_spiral2d(
nspiral=nspiral,
start=start,
stop=stop,
noise_std=noise_std,
a=a, b=b
)
orig_trajs = torch.from_numpy(orig_trajs).float().to(device)
samp_trajs = torch.from_numpy(samp_trajs).float().to(device)
samp_ts = torch.from_numpy(samp_ts).float().to(device)
# model
func = LatentODEfunc(latent_dim, nhidden).to(device)
rec = RecognitionRNN(latent_dim, obs_dim, rnn_nhidden, nspiral).to(device)
dec = Decoder(latent_dim, obs_dim, nhidden).to(device)
params = (list(func.parameters()) + list(dec.parameters()) + list(rec.parameters()))
optimizer = optim.Adam(params, lr=args.lr)
loss_meter = RunningAverageMeter()
if args.train_dir is not None:
if not os.path.exists(args.train_dir):
os.makedirs(args.train_dir)
ckpt_path = os.path.join(args.train_dir, 'ckpt.pth')
if os.path.exists(ckpt_path):
checkpoint = torch.load(ckpt_path)
func.load_state_dict(checkpoint['func_state_dict'])
rec.load_state_dict(checkpoint['rec_state_dict'])
dec.load_state_dict(checkpoint['dec_state_dict'])
optimizer.load_state_dict(checkpoint['optimizer_state_dict'])
orig_trajs = checkpoint['orig_trajs']
samp_trajs = checkpoint['samp_trajs']
orig_ts = checkpoint['orig_ts']
samp_ts = checkpoint['samp_ts']
print('Loaded ckpt from {}'.format(ckpt_path))
try:
for itr in range(1, args.niters + 1):
optimizer.zero_grad()
# backward in time to infer q(z_0)
h = rec.initHidden().to(device)
for t in reversed(range(samp_trajs.size(1))):
obs = samp_trajs[:, t, :]
out, h = rec.forward(obs, h)
qz0_mean, qz0_logvar = out[:, :latent_dim], out[:, latent_dim:]
epsilon = torch.randn(qz0_mean.size()).to(device)
z0 = epsilon * torch.exp(.5 * qz0_logvar) + qz0_mean
# forward in time and solve ode for reconstructions
pred_z = odeint(func, z0, samp_ts).permute(1, 0, 2)
pred_x = dec(pred_z)
# compute loss
noise_std_ = torch.zeros(pred_x.size()).to(device) + noise_std
noise_logvar = 2. * torch.log(noise_std_).to(device)
logpx = log_normal_pdf(
samp_trajs, pred_x, noise_logvar).sum(-1).sum(-1)
pz0_mean = pz0_logvar = torch.zeros(z0.size()).to(device)
analytic_kl = normal_kl(qz0_mean, qz0_logvar,
pz0_mean, pz0_logvar).sum(-1)
loss = torch.mean(-logpx + analytic_kl, dim=0)
loss.backward()
optimizer.step()
loss_meter.update(loss.item())
print('Iter: {}, running avg elbo: {:.4f}'.format(itr, -loss_meter.avg))
except KeyboardInterrupt:
if args.train_dir is not None:
ckpt_path = os.path.join(args.train_dir, 'ckpt.pth')
torch.save({
'func_state_dict': func.state_dict(),
'rec_state_dict': rec.state_dict(),
'dec_state_dict': dec.state_dict(),
'optimizer_state_dict': optimizer.state_dict(),
'orig_trajs': orig_trajs,
'samp_trajs': samp_trajs,
'orig_ts': orig_ts,
'samp_ts': samp_ts,
}, ckpt_path)
print('Stored ckpt at {}'.format(ckpt_path))
print('Training complete after {} iters.'.format(itr))
if args.visualize:
with torch.no_grad():
# sample from trajectorys' approx. posterior
h = rec.initHidden().to(device)
for t in reversed(range(samp_trajs.size(1))):
obs = samp_trajs[:, t, :]
out, h = rec.forward(obs, h)
qz0_mean, qz0_logvar = out[:, :latent_dim], out[:, latent_dim:]
epsilon = torch.randn(qz0_mean.size()).to(device)
z0 = epsilon * torch.exp(.5 * qz0_logvar) + qz0_mean
orig_ts = torch.from_numpy(orig_ts).float().to(device)
# take first trajectory for visualization
z0 = z0[0]
ts_pos = np.linspace(0., 2. * np.pi, num=2000)
ts_neg = np.linspace(-np.pi, 0., num=2000)[::-1].copy()
ts_pos = torch.from_numpy(ts_pos).float().to(device)
ts_neg = torch.from_numpy(ts_neg).float().to(device)
zs_pos = odeint(func, z0, ts_pos)
zs_neg = odeint(func, z0, ts_neg)
xs_pos = dec(zs_pos)
xs_neg = torch.flip(dec(zs_neg), dims=[0])
xs_pos = xs_pos.cpu().numpy()
xs_neg = xs_neg.cpu().numpy()
orig_traj = orig_trajs[0].cpu().numpy()
samp_traj = samp_trajs[0].cpu().numpy()
plt.figure()
plt.plot(orig_traj[:, 0], orig_traj[:, 1],
'g', label='true trajectory')
plt.plot(xs_pos[:, 0], xs_pos[:, 1], 'r',
label='learned trajectory (t>0)')
plt.plot(xs_neg[:, 0], xs_neg[:, 1], 'c',
label='learned trajectory (t<0)')
plt.scatter(samp_traj[:, 0], samp_traj[
:, 1], label='sampled data', s=3)
plt.legend()
plt.savefig('./vis.png', dpi=500)
print('Saved visualization figure at {}'.format('./vis.png'))