https://github.com/GPflow/GPflow
Tip revision: ddeedc6dd96060885edd207bd0772579438e9482 authored by Mark van der Wilk on 10 January 2018, 16:34:42 UTC
Added independent but distinct kernels for multi-output support in `conditional()`.
Added independent but distinct kernels for multi-output support in `conditional()`.
Tip revision: ddeedc6
test_predict.py
# Copyright 2016 the GPflow authors.
#
# 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.from __future__ import print_function
import tensorflow as tf
import numpy as np
import gpflow
from gpflow.test_util import GPflowTestCase
class TestGaussian(GPflowTestCase):
def prepare(self):
self.rng = np.random.RandomState(0)
self.X = self.rng.randn(100, 2)
self.Y = self.rng.randn(100, 1)
self.kern = gpflow.kernels.Matern32(2) + gpflow.kernels.White(1)
self.Xtest = self.rng.randn(10, 2)
self.Ytest = self.rng.randn(10, 1)
# make a Gaussian model
return gpflow.models.GPR(self.X, self.Y, kern=self.kern)
def test_all(self):
with self.test_context():
m = self.prepare()
mu_f, var_f = m.predict_f(self.Xtest)
mu_y, var_y = m.predict_y(self.Xtest)
self.assertTrue(np.allclose(mu_f, mu_y))
self.assertTrue(np.allclose(var_f, var_y - 1.))
def test_density(self):
with self.test_context():
m = self.prepare()
mu_y, var_y = m.predict_y(self.Xtest)
density = m.predict_density(self.Xtest, self.Ytest)
density_hand = (-0.5 * np.log(2 * np.pi) -
0.5 * np.log(var_y) -
0.5 * np.square(mu_y - self.Ytest)/var_y)
self.assertTrue(np.allclose(density_hand, density))
def test_recompile(self):
with self.test_context():
m = self.prepare()
mu_f, var_f = m.predict_f(self.Xtest)
mu_y, var_y = m.predict_y(self.Xtest)
density = m.predict_density(self.Xtest, self.Ytest)
#change a fix and see if these things still compile
m.likelihood.variance = 0.2
m.likelihood.variance.trainable = False
#this will fail unless a recompile has been triggered
mu_f, var_f = m.predict_f(self.Xtest)
mu_y, var_y = m.predict_y(self.Xtest)
density = m.predict_density(self.Xtest, self.Ytest)
class TestFullCov(GPflowTestCase):
"""
this base class requires inherriting to specify the model.
This test structure is more complex that, say, looping over the models, but
makses all the tests much smaller and so less prone to erroring out. Also,
if a test fails, it should be clearer where the error is.
"""
input_dim = 3
output_dim = 2
N = 20
Ntest = 30
M = 5
rng = np.random.RandomState(0)
num_samples = 5
samples_shape = (num_samples, Ntest, output_dim)
covar_shape = (Ntest, Ntest, output_dim)
X = rng.randn(N, input_dim)
Y = rng.randn(N, output_dim)
Z = rng.randn(M, input_dim)
Xtest = rng.randn(Ntest, input_dim)
@classmethod
def kernel(cls):
return gpflow.kernels.Matern32(cls.input_dim)
def prepare(self):
return gpflow.models.GPR(self.X, self.Y, kern=self.kernel())
def test_cov(self):
with self.test_context():
m = self.prepare()
mu1, var = m.predict_f(self.Xtest)
mu2, covar = m.predict_f_full_cov(self.Xtest)
self.assertTrue(np.all(mu1 == mu2))
self.assertTrue(covar.shape == self.covar_shape)
self.assertTrue(var.shape == (self.Ntest, self.output_dim))
for i in range(self.output_dim):
self.assertTrue(np.allclose(var[:, i], np.diag(covar[:, :, i])))
def test_samples(self):
with self.test_context():
m = self.prepare()
samples = m.predict_f_samples(self.Xtest, self.num_samples)
self.assertTrue(samples.shape == self.samples_shape)
class TestFullCovSGPR(TestFullCov):
def prepare(self):
return gpflow.models.SGPR(self.X, self.Y, Z=self.Z, kern=self.kernel())
class TestFullCovGPRFITC(TestFullCov):
def prepare(self):
return gpflow.models.GPRFITC(self.X, self.Y, Z=self.Z, kern=self.kernel())
class TestFullCovSVGP1(TestFullCov):
def prepare(self):
return gpflow.models.SVGP(
self.X, self.Y, Z=self.Z, kern=self.kernel(),
likelihood=gpflow.likelihoods.Gaussian(),
whiten=False, q_diag=True)
class TestFullCovSVGP2(TestFullCov):
def prepare(self):
return gpflow.models.SVGP(
self.X, self.Y, Z=self.Z, kern=self.kernel(),
likelihood=gpflow.likelihoods.Gaussian(),
whiten=True, q_diag=False)
class TestFullCovSVGP3(TestFullCov):
def prepare(self):
return gpflow.models.SVGP(
self.X, self.Y, Z=self.Z, kern=self.kernel(),
likelihood=gpflow.likelihoods.Gaussian(),
whiten=True, q_diag=True)
class TestFullCovSVGP4(TestFullCov):
def prepare(self):
return gpflow.models.SVGP(
self.X, self.Y, Z=self.Z, kern=self.kernel(),
likelihood=gpflow.likelihoods.Gaussian(),
whiten=True, q_diag=False)
class TestFullCovVGP(TestFullCov):
def prepare(self):
return gpflow.models.VGP(
self.X, self.Y, kern=self.kernel(),
likelihood=gpflow.likelihoods.Gaussian())
class TestFullCovGPMC(TestFullCov):
def prepare(self):
return gpflow.models.GPMC(
self.X, self.Y, kern=self.kernel(),
likelihood=gpflow.likelihoods.Gaussian())
class TestFullCovSGPMC(TestFullCov):
def prepare(self):
return gpflow.models.SGPMC(
self.X, self.Y, kern=self.kernel(),
likelihood=gpflow.likelihoods.Gaussian(),
Z=self.Z)
if __name__ == "__main__":
tf.test.main()
