Posit AI Weblog: Moving into the move: Bijectors in TensorFlow Chance

As of right this moment, deep studying’s biggest successes have taken place within the realm of supervised studying, requiring tons and many annotated coaching knowledge. Nonetheless, knowledge doesn’t (usually) include annotations or labels. Additionally, unsupervised studying is engaging due to the analogy to human cognition.

On this weblog to date, we’ve seen two main architectures for unsupervised studying: variational autoencoders and generative adversarial networks. Lesser identified, however interesting for conceptual in addition to for efficiency causes are normalizing flows (Jimenez Rezende and Mohamed 2015). On this and the following put up, we’ll introduce flows, specializing in methods to implement them utilizing TensorFlow Chance (TFP).

In distinction to earlier posts involving TFP that accessed its performance utilizing low-level $-syntax, we now make use of tfprobability, an R wrapper within the fashion of keras, tensorflow and tfdatasets. A observe concerning this bundle: It’s nonetheless beneath heavy growth and the API might change. As of this writing, wrappers don’t but exist for all TFP modules, however all TFP performance is on the market utilizing $-syntax if want be.

Density estimation and sampling

Again to unsupervised studying, and particularly pondering of variational autoencoders, what are the primary issues they offer us? One factor that’s seldom lacking from papers on generative strategies are footage of super-real-looking faces (or mattress rooms, or animals …). So evidently sampling (or: era) is a crucial half. If we are able to pattern from a mannequin and acquire real-seeming entities, this implies the mannequin has realized one thing about how issues are distributed on the earth: it has realized a distribution.
Within the case of variational autoencoders, there’s extra: The entities are imagined to be decided by a set of distinct, disentangled (hopefully!) latent components. However this isn’t the idea within the case of normalizing flows, so we aren’t going to elaborate on this right here.

As a recap, how can we pattern from a VAE? We draw from (z), the latent variable, and run the decoder community on it. The end result ought to – we hope – appear to be it comes from the empirical knowledge distribution. It mustn’t, nevertheless, look precisely like several of the gadgets used to coach the VAE, or else we’ve not realized something helpful.

The second factor we might get from a VAE is an evaluation of the plausibility of particular person knowledge, for use, for instance, in anomaly detection. Right here “plausibility” is obscure on goal: With VAE, we don’t have a method to compute an precise density beneath the posterior.

What if we wish, or want, each: era of samples in addition to density estimation? That is the place normalizing flows are available in.

Normalizing flows

A move is a sequence of differentiable, invertible mappings from knowledge to a “good” distribution, one thing we are able to simply pattern from and use to calculate a density. Let’s take as instance the canonical solution to generate samples from some distribution, the exponential, say.

We begin by asking our random quantity generator for some quantity between 0 and 1:

This quantity we deal with as coming from a cumulative likelihood distribution (CDF) – from an exponential CDF, to be exact. Now that we’ve a price from the CDF, all we have to do is map that “again” to a price. That mapping CDF -> worth we’re in search of is simply the inverse of the CDF of an exponential distribution, the CDF being

[F(x) = 1 – e^{-lambda x}]

The inverse then is

[
F^{-1}(u) = -frac{1}{lambda} ln (1 – u)
]

which suggests we might get our exponential pattern doing

lambda <- 0.5 # choose some lambda
x <- -1/lambda * log(1-u)

We see the CDF is definitely a move (or a constructing block thereof, if we image most flows as comprising a number of transformations), since

• It maps knowledge to a uniform distribution between 0 and 1, permitting to evaluate knowledge chance.
• Conversely, it maps a likelihood to an precise worth, thus permitting to generate samples.

From this instance, we see why a move must be invertible, however we don’t but see why it must be differentiable. It will turn into clear shortly, however first let’s check out how flows can be found in tfprobability.

Bijectors

TFP comes with a treasure trove of transformations, known as bijectors, starting from easy computations like exponentiation to extra advanced ones just like the discrete cosine rework.

To get began, let’s use tfprobability to generate samples from the traditional distribution.
There’s a bijector tfb_normal_cdf() that takes enter knowledge to the interval ([0,1]). Its inverse rework then yields a random variable with the usual regular distribution:

Conversely, we are able to use this bijector to find out the (log) likelihood of a pattern from the traditional distribution. We’ll test in opposition to a simple use of tfd_normal within the distributions module:

x <- 2.01
d_n <- tfd_normal(loc = 0, scale = 1) 

d_n %>% tfd_log_prob(x) %>% as.numeric() # -2.938989

To acquire that very same log likelihood from the bijector, we add two parts:

• Firstly, we run the pattern by way of the ahead transformation and compute log likelihood beneath the uniform distribution.
• Secondly, as we’re utilizing the uniform distribution to find out likelihood of a traditional pattern, we have to observe how likelihood adjustments beneath this transformation. That is accomplished by calling tfb_forward_log_det_jacobian (to be additional elaborated on under).

b <- tfb_normal_cdf()
d_u <- tfd_uniform()

l <- d_u %>% tfd_log_prob(b %>% tfb_forward(x))
j <- b %>% tfb_forward_log_det_jacobian(x, event_ndims = 0)

(l + j) %>% as.numeric() # -2.938989

Why does this work? Let’s get some background.

Chance mass is conserved

Flows are based mostly on the precept that beneath transformation, likelihood mass is conserved. Say we’ve a move from (x) to (z):
[z = f(x)]

Suppose we pattern from (z) after which, compute the inverse rework to acquire (x). We all know the likelihood of (z). What’s the likelihood that (x), the remodeled pattern, lies between (x_0) and (x_0 + dx)?

This likelihood is (p(x) dx), the density instances the size of the interval. This has to equal the likelihood that (z) lies between (f(x)) and (f(x + dx)). That new interval has size (f'(x) dx), so:

[p(x) dx = p(z) f'(x) dx]

Or equivalently

[p(x) = p(z) * dz/dx]

Thus, the pattern likelihood (p(x)) is decided by the bottom likelihood (p(z)) of the remodeled distribution, multiplied by how a lot the move stretches area.

The identical goes in larger dimensions: Once more, the move is concerning the change in likelihood quantity between the (z) and (y) areas:

[p(x) = p(z) frac{vol(dz)}{vol(dx)}]

In larger dimensions, the Jacobian replaces the by-product. Then, the change in quantity is captured by absolutely the worth of its determinant:

[p(mathbf{x}) = p(f(mathbf{x})) bigg|detfrac{partial f({mathbf{x})}}{partial{mathbf{x}}}bigg|]

In follow, we work with log possibilities, so

[log p(mathbf{x}) = log p(f(mathbf{x})) + log bigg|detfrac{partial f({mathbf{x})}}{partial{mathbf{x}}}bigg| ]

Let’s see this with one other bijector instance, tfb_affine_scalar. Beneath, we assemble a mini-flow that maps just a few arbitrary chosen (x) values to double their worth (scale = 2):

x <- c(0, 0.5, 1)
b <- tfb_affine_scalar(shift = 0, scale = 2)

To check densities beneath the move, we select the traditional distribution, and have a look at the log densities:

d_n <- tfd_normal(loc = 0, scale = 1)
d_n %>% tfd_log_prob(x) %>% as.numeric() # -0.9189385 -1.0439385 -1.4189385

Now apply the move and compute the brand new log densities as a sum of the log densities of the corresponding (x) values and the log determinant of the Jacobian:

z <- b %>% tfb_forward(x)

(d_n  %>% tfd_log_prob(b %>% tfb_inverse(z))) +
  (b %>% tfb_inverse_log_det_jacobian(z, event_ndims = 0)) %>%
  as.numeric() # -1.6120857 -1.7370857 -2.1120858

We see that because the values get stretched in area (we multiply by 2), the person log densities go down.
We are able to confirm the cumulative likelihood stays the identical utilizing tfd_transformed_distribution():

d_t <- tfd_transformed_distribution(distribution = d_n, bijector = b)
d_n %>% tfd_cdf(x) %>% as.numeric()  # 0.5000000 0.6914625 0.8413447

d_t %>% tfd_cdf(y) %>% as.numeric()  # 0.5000000 0.6914625 0.8413447

Up to now, the flows we noticed have been static – how does this match into the framework of neural networks?

Coaching a move

Provided that flows are bidirectional, there are two methods to consider them. Above, we’ve largely harassed the inverse mapping: We would like a easy distribution we are able to pattern from, and which we are able to use to compute a density. In that line, flows are generally known as “mappings from knowledge to noise” – noise largely being an isotropic Gaussian. Nonetheless in follow, we don’t have that “noise” but, we simply have knowledge.
So in follow, we’ve to study a move that does such a mapping. We do that through the use of bijectors with trainable parameters.
We’ll see a quite simple instance right here, and depart “actual world flows” to the following put up.

The instance is predicated on half 1 of Eric Jang’s introduction to normalizing flows. The primary distinction (other than simplification to point out the fundamental sample) is that we’re utilizing keen execution.

We begin from a two-dimensional, isotropic Gaussian, and we wish to mannequin knowledge that’s additionally regular, however with a imply of 1 and a variance of two (in each dimensions).

library(tensorflow)
library(tfprobability)

tfe_enable_eager_execution(device_policy = "silent")

library(tfdatasets)

# the place we begin from
base_dist <- tfd_multivariate_normal_diag(loc = c(0, 0))

# the place we wish to go
target_dist <- tfd_multivariate_normal_diag(loc = c(1, 1), scale_identity_multiplier = 2)

# create coaching knowledge from the goal distribution
target_samples <- target_dist %>% tfd_sample(1000) %>% tf$solid(tf$float32)

batch_size <- 100
dataset <- tensor_slices_dataset(target_samples) %>%
  dataset_shuffle(buffer_size = dim(target_samples)[1]) %>%
  dataset_batch(batch_size)

Now we’ll construct a tiny neural community, consisting of an affine transformation and a nonlinearity.
For the previous, we are able to make use of tfb_affine, the multi-dimensional relative of tfb_affine_scalar.
As to nonlinearities, presently TFP comes with tfb_sigmoid and tfb_tanh, however we are able to construct our personal parameterized ReLU utilizing tfb_inline:

# alpha is a learnable parameter
bijector_leaky_relu <- perform(alpha) {
  
  tfb_inline(
    # ahead rework leaves constructive values untouched and scales unfavorable ones by alpha
    forward_fn = perform(x)
      tf$the place(tf$greater_equal(x, 0), x, alpha * x),
    # inverse rework leaves constructive values untouched and scales unfavorable ones by 1/alpha
    inverse_fn = perform(y)
      tf$the place(tf$greater_equal(y, 0), y, 1/alpha * y),
    # quantity change is 0 when constructive and 1/alpha when unfavorable
    inverse_log_det_jacobian_fn = perform(y) {
      I <- tf$ones_like(y)
      J_inv <- tf$the place(tf$greater_equal(y, 0), I, 1/alpha * I)
      log_abs_det_J_inv <- tf$log(tf$abs(J_inv))
      tf$reduce_sum(log_abs_det_J_inv, axis = 1L)
    },
    forward_min_event_ndims = 1
  )
}

Outline the learnable variables for the affine and the PReLU layers:

d <- 2 # dimensionality
r <- 2 # rank of replace

# shift of affine bijector
shift <- tf$get_variable("shift", d)
# scale of affine bijector
L <- tf$get_variable('L', c(d * (d + 1) / 2))
# rank-r replace
V <- tf$get_variable("V", c(d, r))

# scaling issue of parameterized relu
alpha <- tf$abs(tf$get_variable('alpha', checklist())) + 0.01

With keen execution, the variables have for use contained in the loss perform, so that’s the place we outline the bijectors. Our little move now could be a tfb_chain of bijectors, and we wrap it in a TransformedDistribution (tfd_transformed_distribution) that hyperlinks supply and goal distributions.

loss <- perform() {
  
 affine <- tfb_affine(
        scale_tril = tfb_fill_triangular() %>% tfb_forward(L),
        scale_perturb_factor = V,
        shift = shift
      )
 lrelu <- bijector_leaky_relu(alpha = alpha)  
 
 move <- checklist(lrelu, affine) %>% tfb_chain()
 
 dist <- tfd_transformed_distribution(distribution = base_dist,
                          bijector = move)
  
 l <- -tf$reduce_mean(dist$log_prob(batch))
 # hold observe of progress
 print(spherical(as.numeric(l), 2))
 l
}

Now we are able to truly run the coaching!

optimizer <- tf$practice$AdamOptimizer(1e-4)

n_epochs <- 100
for (i in 1:n_epochs) {
  iter <- make_iterator_one_shot(dataset)
  until_out_of_range({
    batch <- iterator_get_next(iter)
    optimizer$reduce(loss)
  })
}

Outcomes will differ relying on random initialization, however it is best to see a gradual (if sluggish) progress. Utilizing bijectors, we’ve truly educated and outlined somewhat neural community.

Outlook

Undoubtedly, this move is just too easy to mannequin advanced knowledge, however it’s instructive to have seen the fundamental ideas earlier than delving into extra advanced flows. Within the subsequent put up, we’ll try autoregressive flows, once more utilizing TFP and tfprobability.