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meta_test.py
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meta_test.py
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# Copyright 2016 Google Inc.
#
# 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.
# ==============================================================================
"""Tests for L2L meta-optimizer."""
from __future__ import absolute_import
from __future__ import division
from __future__ import print_function
import os
import tempfile
from nose_parameterized import parameterized
import numpy as np
from six.moves import xrange
import sonnet as snt
import tensorflow as tf
import meta
import problems
def train(sess, minimize_ops, num_epochs, num_unrolls):
"""L2L training."""
step, update, reset, loss_last, x_last = minimize_ops
for _ in xrange(num_epochs):
sess.run(reset)
for _ in xrange(num_unrolls):
cost, final_x, unused_1, unused_2 = sess.run([loss_last, x_last,
update, step])
return cost, final_x
class L2LTest(tf.test.TestCase):
"""Tests L2L meta-optimizer."""
def testResults(self):
"""Tests reproducibility of Torch results."""
problem = problems.simple()
optimizer = meta.MetaOptimizer(net=dict(
net="CoordinateWiseDeepLSTM",
net_options={
"layers": (),
"initializer": "zeros"
}))
minimize_ops = optimizer.meta_minimize(problem, 5)
with self.test_session() as sess:
sess.run(tf.global_variables_initializer())
cost, final_x = train(sess, minimize_ops, 1, 2)
# Torch results
torch_cost = 0.7325327
torch_final_x = 0.8559
self.assertAlmostEqual(cost, torch_cost, places=4)
self.assertAlmostEqual(final_x[0], torch_final_x, places=4)
@parameterized.expand([
# Shared optimizer.
(
None,
{
"net": {
"net": "CoordinateWiseDeepLSTM",
"net_options": {"layers": (1, 1,)}
}
}
),
# Explicit sharing.
(
[("net", ["x_0", "x_1"])],
{
"net": {
"net": "CoordinateWiseDeepLSTM",
"net_options": {"layers": (1,)}
}
}
),
# Different optimizers.
(
[("net1", ["x_0"]), ("net2", ["x_1"])],
{
"net1": {
"net": "CoordinateWiseDeepLSTM",
"net_options": {"layers": (1,)}
},
"net2": {"net": "Adam"}
}
),
# Different optimizers for the same variable.
(
[("net1", ["x_0"]), ("net2", ["x_0"])],
{
"net1": {
"net": "CoordinateWiseDeepLSTM",
"net_options": {"layers": (1,)}
},
"net2": {
"net": "CoordinateWiseDeepLSTM",
"net_options": {"layers": (1,)}
}
}
),
])
def testMultiOptimizer(self, net_assignments, net_config):
"""Tests different variable->net mappings in multi-optimizer problem."""
problem = problems.simple_multi_optimizer(num_dims=2)
optimizer = meta.MetaOptimizer(**net_config)
minimize_ops = optimizer.meta_minimize(problem, 3,
net_assignments=net_assignments)
with self.test_session() as sess:
sess.run(tf.global_variables_initializer())
train(sess, minimize_ops, 1, 2)
def testSecondDerivatives(self):
"""Tests second derivatives for simple problem."""
problem = problems.simple()
optimizer = meta.MetaOptimizer(net=dict(
net="CoordinateWiseDeepLSTM",
net_options={"layers": ()}))
minimize_ops = optimizer.meta_minimize(problem, 3,
second_derivatives=True)
with self.test_session() as sess:
sess.run(tf.global_variables_initializer())
train(sess, minimize_ops, 1, 2)
def testConvolutional(self):
"""Tests L2L applied to problem with convolutions."""
kernel_shape = 4
def convolutional_problem():
conv = snt.Conv2D(output_channels=1,
kernel_shape=kernel_shape,
stride=1,
name="conv")
output = conv(tf.random_normal((100, 100, 3, 10)))
return tf.reduce_sum(output)
net_config = {
"conv": {
"net": "KernelDeepLSTM",
"net_options": {
"kernel_shape": [kernel_shape] * 2,
"layers": (5,)
},
},
}
optimizer = meta.MetaOptimizer(**net_config)
minimize_ops = optimizer.meta_minimize(
convolutional_problem, 3,
net_assignments=[("conv", ["conv/w"])]
)
with self.test_session() as sess:
sess.run(tf.global_variables_initializer())
train(sess, minimize_ops, 1, 2)
def testWhileLoopProblem(self):
"""Tests L2L applied to problem with while loop."""
def while_loop_problem():
x = tf.get_variable("x", shape=[], initializer=tf.ones_initializer())
# Strange way of squaring the variable.
_, x_squared = tf.while_loop(
cond=lambda t, _: t < 1,
body=lambda t, x: (t + 1, x * x),
loop_vars=(0, x),
name="loop")
return x_squared
optimizer = meta.MetaOptimizer(net=dict(
net="CoordinateWiseDeepLSTM",
net_options={"layers": ()}))
minimize_ops = optimizer.meta_minimize(while_loop_problem, 3)
with self.test_session() as sess:
sess.run(tf.global_variables_initializer())
train(sess, minimize_ops, 1, 2)
def testSaveAndLoad(self):
"""Tests saving and loading a meta-optimizer."""
layers = (2, 3)
net_options = {"layers": layers, "initializer": "zeros"}
num_unrolls = 2
num_epochs = 1
problem = problems.simple()
# Original optimizer.
with tf.Graph().as_default() as g1:
optimizer = meta.MetaOptimizer(net=dict(
net="CoordinateWiseDeepLSTM",
net_options=net_options))
minimize_ops = optimizer.meta_minimize(problem, 3)
with self.test_session(graph=g1) as sess:
sess.run(tf.global_variables_initializer())
train(sess, minimize_ops, 1, 2)
# Save optimizer.
tmp_dir = tempfile.mkdtemp()
save_result = optimizer.save(sess, path=tmp_dir)
net_path = next(iter(save_result))
# Retrain original optimizer.
cost, x = train(sess, minimize_ops, num_unrolls, num_epochs)
# Load optimizer and retrain in a new session.
with tf.Graph().as_default() as g2:
optimizer = meta.MetaOptimizer(net=dict(
net="CoordinateWiseDeepLSTM",
net_options=net_options,
net_path=net_path))
minimize_ops = optimizer.meta_minimize(problem, 3)
with self.test_session(graph=g2) as sess:
sess.run(tf.global_variables_initializer())
cost_loaded, x_loaded = train(sess, minimize_ops, num_unrolls, num_epochs)
# The last cost should be the same.
self.assertAlmostEqual(cost, cost_loaded, places=3)
self.assertAlmostEqual(x[0], x_loaded[0], places=3)
# Cleanup.
os.remove(net_path)
os.rmdir(tmp_dir)
if __name__ == "__main__":
tf.test.main()