https://github.com/GPflow/GPflow
Tip revision: 2b0e60b4dec5ee701d4a6e5fc0053afbc007c969 authored by Artem Artemev on 17 June 2019, 08:11:06 UTC
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sgpr.py
# Copyright 2016 James Hensman, alexggmatthews, Mark van der Wilk
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
import numpy as np
import tensorflow as tf
from gpflow.features import InducingPoints
from gpflow.covariances.dispatch import Kuf, Kuu
from gpflow.config import default_float, default_jitter
from .model import GPModel, GPModelOLD, MeanAndVariance
from .. import features
from .. import likelihoods
from ..mean_functions import Zero
class SGPRUpperMixin(object):
"""
Upper bound for the GP regression marginal likelihood.
It is implemented here as a Mixin class which works with SGPR and GPRFITC.
Note that the same inducing points are used for calculating the upper bound,
as are used for computing the likelihood approximation. This may not lead to
the best upper bound. The upper bound can be tightened by optimising Z, just
as just like the lower bound. This is especially important in FITC, as FITC
is known to produce poor inducing point locations. An optimisable upper bound
can be found in https://github.com/markvdw/gp_upper.
The key reference is
::
@misc{titsias_2014,
title={Variational Inference for Gaussian and Determinantal Point Processes},
url={http://www2.aueb.gr/users/mtitsias/papers/titsiasNipsVar14.pdf},
publisher={Workshop on Advances in Variational Inference (NIPS 2014)},
author={Titsias, Michalis K.},
year={2014},
month={Dec}
}
"""
def upper_bound(self):
num_data = tf.cast(tf.shape(self.Y)[0], default_float())
Kdiag = self.kernel(self.X)
kuu = Kuu(self.feature, self.kernel, jitter=default_jitter())
kuf = Kuf(self.feature, self.kernel, self.X)
L = tf.linalg.cholesky(kuu)
LB = tf.linalg.cholesky(kuu + self.likelihood.variance**-1.0 *
tf.linalg.matmul(kuf, kuf, transpose_b=True))
Linvkuf = tf.linalg.triangular_solve(L, kuf, lower=True)
# Using the Trace bound, from Titsias' presentation
c = tf.reduce_sum(Kdiag) - tf.reduce_sum(Linvkuf**2.0)
# Kff = self.kernel(self.X)
# Qff = tf.linalg.matmul(kuf, Linvkuf, transpose_a=True)
# Alternative bound on max eigenval:
# c = tf.reduce_max(tf.reduce_sum(tf.abs(Kff - Qff), 0))
corrected_noise = self.likelihood.variance + c
const = -0.5 * num_data * tf.math.log(
2 * np.pi * self.likelihood.variance)
logdet = tf.reduce_sum(tf.math.log(
tf.linalg.diag_part(L))) - tf.reduce_sum(
tf.math.log(tf.linalg.diag_part(LB)))
LC = tf.linalg.cholesky(kuu + corrected_noise**-1.0 *
tf.linalg.matmul(kuf, kuf, transpose_b=True))
v = tf.linalg.triangular_solve(LC,
corrected_noise**-1.0 *
tf.linalg.matmul(kuf, self.Y),
lower=True)
quad = -0.5 * corrected_noise**-1.0 * tf.reduce_sum(
self.Y**2.0) + 0.5 * tf.reduce_sum(v**2.0)
return const + logdet + quad
class SGPR(GPModelOLD, SGPRUpperMixin):
"""
Sparse Variational GP regression. The key reference is
::
@inproceedings{titsias2009variational,
title={Variational learning of inducing variables in
sparse Gaussian processes},
author={Titsias, Michalis K},
booktitle={International Conference on
Artificial Intelligence and Statistics},
pages={567--574},
year={2009}
}
"""
def __init__(self,
X,
Y,
kernel,
mean_function=None,
features=None,
**kwargs):
"""
X is a data matrix, size [N, D]
Y is a data matrix, size [N, R]
Z is a matrix of pseudo inputs, size [M, D]
kernel, mean_function are appropriate GPflow objects
This method only works with a Gaussian likelihood.
"""
likelihood = likelihoods.Gaussian()
GPModelOLD.__init__(self, X, Y, kernel, likelihood, mean_function,
**kwargs)
self.feature = InducingPoints(features)
self.num_data = X.shape[0]
def log_likelihood(self):
"""
Construct a tensorflow function to compute the bound on the marginal
likelihood. For a derivation of the terms in here, see the associated
SGPR notebook.
"""
num_inducing = len(self.feature)
num_data = tf.cast(tf.shape(self.Y)[0], default_float())
output_dim = tf.cast(tf.shape(self.Y)[1], default_float())
err = self.Y - self.mean_function(self.X)
Kdiag = self.kernel(self.X)
kuf = Kuf(self.feature, self.kernel, self.X)
kuu = Kuu(self.feature, self.kernel, jitter=default_jitter())
L = tf.linalg.cholesky(kuu)
sigma = tf.sqrt(self.likelihood.variance)
# Compute intermediate matrices
A = tf.linalg.triangular_solve(L, kuf, lower=True) / sigma
AAT = tf.linalg.matmul(A, A, transpose_b=True)
B = AAT + tf.eye(num_inducing, dtype=default_float())
LB = tf.linalg.cholesky(B)
Aerr = tf.linalg.matmul(A, err)
c = tf.linalg.triangular_solve(LB, Aerr, lower=True) / sigma
# compute log marginal bound
bound = -0.5 * num_data * output_dim * np.log(2 * np.pi)
bound += tf.negative(output_dim) * tf.reduce_sum(
tf.math.log(tf.linalg.diag_part(LB)))
bound -= 0.5 * num_data * output_dim * tf.math.log(
self.likelihood.variance)
bound += -0.5 * tf.reduce_sum(
tf.square(err)) / self.likelihood.variance
bound += 0.5 * tf.reduce_sum(tf.square(c))
bound += -0.5 * output_dim * tf.reduce_sum(
Kdiag) / self.likelihood.variance
bound += 0.5 * output_dim * tf.reduce_sum(tf.linalg.diag_part(AAT))
return bound
def predict_f(self, X: tf.Tensor, full_cov=False,
full_output_cov=False) -> MeanAndVariance:
"""
Compute the mean and variance of the latent function at some new points
Xnew. For a derivation of the terms in here, see the associated SGPR
notebook.
"""
num_inducing = len(self.feature)
err = self.Y - self.mean_function(self.X)
kuf = Kuf(self.feature, self.kernel, self.X)
kuu = Kuu(self.feature, self.kernel, jitter=default_jitter())
Kus = Kuf(self.feature, self.kernel, X)
sigma = tf.sqrt(self.likelihood.variance)
L = tf.linalg.cholesky(kuu)
A = tf.linalg.triangular_solve(L, kuf, lower=True) / sigma
B = tf.linalg.matmul(A, A, transpose_b=True) + tf.eye(
num_inducing, dtype=default_float())
LB = tf.linalg.cholesky(B)
Aerr = tf.linalg.matmul(A, err)
c = tf.linalg.triangular_solve(LB, Aerr, lower=True) / sigma
tmp1 = tf.linalg.triangular_solve(L, Kus, lower=True)
tmp2 = tf.linalg.triangular_solve(LB, tmp1, lower=True)
mean = tf.linalg.matmul(tmp2, c, transpose_a=True)
if full_cov:
var = self.kernel(X) + tf.linalg.matmul(tmp2, tmp2, transpose_a=True) \
- tf.linalg.matmul(tmp1, tmp1, transpose_a=True)
var = tf.tile(var[None, ...], [self.num_latent, 1, 1]) # [P, N, N]
else:
var = self.kernel(X, full=False) + tf.reduce_sum(tf.square(tmp2), 0) \
- tf.reduce_sum(tf.square(tmp1), 0)
var = tf.tile(var[:, None], [1, self.num_latent])
return mean + self.mean_function(X), var
class GPRFITC(GPModelOLD, SGPRUpperMixin):
def __init__(self,
X,
Y,
kernel,
mean_function=None,
features=None,
**kwargs):
"""
This implements GP regression with the FITC approximation.
The key reference is
@inproceedings{Snelson06sparsegaussian,
author = {Edward Snelson and Zoubin Ghahramani},
title = {Sparse Gaussian Processes using Pseudo-inputs},
booktitle = {Advances In Neural Information Processing Systems },
year = {2006},
pages = {1257--1264},
publisher = {MIT press}
}
Implementation loosely based on code from GPML matlab library although
obviously gradients are automatic in GPflow.
X is a data matrix, size [N, D]
Y is a data matrix, size [N, R]
Z is a matrix of pseudo inputs, size [M, D]
kernel, mean_function are appropriate GPflow objects
This method only works with a Gaussian likelihood.
"""
mean_function = Zero() if mean_function is None else mean_function
likelihood = likelihoods.Gaussian()
GPModelOLD.__init__(self, X, Y, kernel, likelihood, mean_function,
**kwargs)
self.feature = InducingPoints(features)
self.num_data = X.shape[0]
self.num_latent = Y.shape[1]
def common_terms(self):
num_inducing = len(self.feature)
err = self.Y - self.mean_function(self.X) # size [N, R]
Kdiag = self.kernel(self.X, full=False)
kuf = Kuf(self.feature, self.kernel, self.X)
kuu = Kuu(self.feature, self.kernel, jitter=default_jitter())
Luu = tf.linalg.cholesky(kuu) # => Luu Luu^T = kuu
V = tf.linalg.triangular_solve(
Luu, kuf) # => V^T V = Qff = kuf^T kuu^-1 kuf
diagQff = tf.reduce_sum(tf.square(V), 0)
nu = Kdiag - diagQff + self.likelihood.variance
B = tf.eye(num_inducing, dtype=default_float()) + tf.linalg.matmul(
V / nu, V, transpose_b=True)
L = tf.linalg.cholesky(B)
beta = err / tf.expand_dims(nu, 1) # size [N, R]
alpha = tf.linalg.matmul(V, beta) # size [N, R]
gamma = tf.linalg.triangular_solve(L, alpha, lower=True) # size [N, R]
return err, nu, Luu, L, alpha, beta, gamma
def log_likelihood(self):
"""
Construct a tensorflow function to compute the bound on the marginal
likelihood.
"""
# FITC approximation to the log marginal likelihood is
# log ( normal( y | mean, K_fitc ) )
# where K_fitc = Qff + diag( \nu )
# where Qff = Kfu kuu^{-1} kuf
# with \nu_i = Kff_{i,i} - Qff_{i,i} + \sigma^2
# We need to compute the Mahalanobis term -0.5* err^T K_fitc^{-1} err
# (summed over functions).
# We need to deal with the matrix inverse term.
# K_fitc^{-1} = ( Qff + \diag( \nu ) )^{-1}
# = ( V^T V + \diag( \nu ) )^{-1}
# Applying the Woodbury identity we obtain
# = \diag( \nu^{-1} ) - \diag( \nu^{-1} ) V^T ( I + V \diag( \nu^{-1} ) V^T )^{-1) V \diag(\nu^{-1} )
# Let \beta = \diag( \nu^{-1} ) err
# and let \alpha = V \beta
# then Mahalanobis term = -0.5* ( \beta^T err - \alpha^T Solve( I + V \diag( \nu^{-1} ) V^T, alpha ) )
err, nu, Luu, L, alpha, beta, gamma = self.common_terms()
mahalanobisTerm = -0.5 * tf.reduce_sum(tf.square(err) / tf.expand_dims(nu, 1)) \
+ 0.5 * tf.reduce_sum(tf.square(gamma))
# We need to compute the log normalizing term -N/2 \log 2 pi - 0.5 \log \det( K_fitc )
# We need to deal with the log determinant term.
# \log \det( K_fitc ) = \log \det( Qff + \diag( \nu ) )
# = \log \det( V^T V + \diag( \nu ) )
# Applying the determinant lemma we obtain
# = \log [ \det \diag( \nu ) \det( I + V \diag( \nu^{-1} ) V^T ) ]
# = \log [ \det \diag( \nu ) ] + \log [ \det( I + V \diag( \nu^{-1} ) V^T ) ]
constantTerm = -0.5 * self.num_data * tf.math.log(
tf.constant(2. * np.pi, default_float()))
logDeterminantTerm = -0.5 * tf.reduce_sum(
tf.math.log(nu)) - tf.reduce_sum(
tf.math.log(tf.linalg.diag_part(L)))
logNormalizingTerm = constantTerm + logDeterminantTerm
return mahalanobisTerm + logNormalizingTerm * self.num_latent
def predict_f(self, X: tf.Tensor, full_cov=False,
full_output_cov=False) -> MeanAndVariance:
"""
Compute the mean and variance of the latent function at some new points
Xnew.
"""
_, _, Luu, L, _, _, gamma = self.common_terms()
Kus = Kuf(self.feature, self.kernel, X) # size [M, X]new
w = tf.linalg.triangular_solve(Luu, Kus, lower=True) # size [M, X]new
tmp = tf.linalg.triangular_solve(tf.transpose(L), gamma, lower=False)
mean = tf.linalg.matmul(w, tmp,
transpose_a=True) + self.mean_function(X)
intermediateA = tf.linalg.triangular_solve(L, w, lower=True)
if full_cov:
var = self.kernel(X) - tf.linalg.matmul(w, w, transpose_a=True) \
+ tf.linalg.matmul(intermediateA, intermediateA, transpose_a=True)
var = tf.tile(var[None, ...], [self.num_latent, 1, 1]) # [P, N, N]
else:
var = self.kernel(X, full=False) - tf.reduce_sum(tf.square(w), 0) \
+ tf.reduce_sum(tf.square(intermediateA), 0) # size Xnew,
var = tf.tile(var[:, None], [1, self.num_latent])
return mean, var
@property
def Z(self):
raise NotImplementedError(
"Inducing points are now in `model.feature.Z()`.")
@Z.setter
def Z(self, _):
raise NotImplementedError(
"Inducing points are now in `model.feature.Z()`.")