Source code for neupi.training.pm_ssl.nam.made
import numpy as np
import torch
import torch.nn as nn
import torch.nn.functional as F
# ------------------------------------------------------------------------------
from neupi.core.model import BaseProbModel
from neupi.registry import register
@register("nn_model")
class MaskedLinear(BaseProbModel):
"""same as Linear except has a configurable mask on the weights"""
def __init__(self, in_features, out_features, bias=True):
super().__init__(in_features, out_features, bias)
self.register_buffer("mask", torch.ones(out_features, in_features))
def set_mask(self, mask):
self.mask.data.copy_(torch.from_numpy(mask.astype(np.uint8).T))
def forward(self, input):
return F.linear(input, self.mask * self.weight, self.bias)
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class MADE(nn.Module):
def __init__(self, nin, hidden_sizes, nout, num_masks=1, natural_ordering=False):
"""
nin: integer; number of inputs
hidden sizes: a list of integers; number of units in hidden layers
nout: integer; number of outputs, which usually collectively parameterize some kind of 1D distribution
note: if nout is e.g. 2x larger than nin (perhaps the mean and std), then the first nin
will be all the means and the second nin will be stds. i.e. output dimensions depend on the
same input dimensions in "chunks" and should be carefully decoded downstream appropriately.
the output of running the tests for this file makes this a bit more clear with examples.
num_masks: can be used to train ensemble over orderings/connections
natural_ordering: force natural ordering of dimensions, don't use random permutations
"""
super().__init__()
self.nin = nin
self.nout = nout
self.hidden_sizes = hidden_sizes
self.sigmoid = nn.Sigmoid()
assert self.nout % self.nin == 0, "nout must be integer multiple of nin"
# define a simple MLP neural net
self.net = []
hs = [nin] + hidden_sizes + [nout]
for h0, h1 in zip(hs, hs[1:]):
self.net.extend(
[
MaskedLinear(h0, h1),
nn.ReLU(),
]
)
self.net.pop() # pop the last ReLU for the output layer
self.net = nn.Sequential(*self.net)
# seeds for orders/connectivities of the model ensemble
self.natural_ordering = natural_ordering
self.num_masks = num_masks
self.seed = 0 # for cycling through num_masks orderings
self.m = {}
self.update_masks()
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def update_masks(self):
if self.m and self.num_masks == 1:
return
L = len(self.hidden_sizes)
# fetch the next seed and construct a random stream
rng = np.random.RandomState(self.seed)
self.seed = (self.seed + 1) % self.num_masks
# sample the order of the inputs and the connectivity of all neurons
self.m[-1] = np.arange(self.nin) if self.natural_ordering else rng.permutation(self.nin)
for l in range(L):
self.m[l] = rng.randint(self.m[l - 1].min(), self.nin - 1, size=self.hidden_sizes[l])
# construct the mask matrices
masks = [self.m[l - 1][:, None] <= self.m[l][None, :] for l in range(L)]
masks.append(self.m[L - 1][:, None] < self.m[-1][None, :])
# handle the case where nout = nin * k, for integer k > 1
if self.nout > self.nin:
k = int(self.nout / self.nin)
# replicate the mask across the other outputs
masks[-1] = np.concatenate([masks[-1]] * k, axis=1)
# set the masks in all MaskedLinear layers
layers = [l for l in self.net.modules() if isinstance(l, MaskedLinear)]
for l, m in zip(layers, masks):
l.set_mask(m)
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def forward(self, x):
return self.net(x)
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def evaluate(self, x):
distributions = self(x)
# This is a more numerically stable implementation of the log likelihood - uses logsumexp trick
log_likelihoods = -(F.binary_cross_entropy_with_logits(distributions, x, reduction="none"))
log_likelihoods = torch.sum(log_likelihoods, dim=1)
return log_likelihoods