tensorflow/python/training/adagrad_da_test.py
# Copyright 2016 The TensorFlow Authors. All Rights Reserved.
#
# 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.
# ==============================================================================
"""Functional tests for AdagradDA operations."""
import numpy as np
from tensorflow.python.framework import constant_op
from tensorflow.python.framework import dtypes
from tensorflow.python.framework import ops
from tensorflow.python.framework import test_util
from tensorflow.python.ops import embedding_ops
from tensorflow.python.ops import math_ops
from tensorflow.python.ops import resource_variable_ops
from tensorflow.python.ops import variables
from tensorflow.python.platform import test
from tensorflow.python.training import adagrad_da
class AdagradDAOptimizerTest(test.TestCase):
def doTestAdagradDAwithoutRegularizationBasic1(self, use_resource=False):
for dtype in [dtypes.float64, dtypes.float32]:
with ops.Graph().as_default(), self.cached_session():
global_step = variables.Variable(0, dtype=dtypes.int64)
if use_resource:
var0 = resource_variable_ops.ResourceVariable([0.0, 0.0], dtype=dtype)
var1 = resource_variable_ops.ResourceVariable([0.0, 0.0], dtype=dtype)
else:
var0 = variables.Variable([0.0, 0.0], dtype=dtype)
var1 = variables.Variable([0.0, 0.0], dtype=dtype)
grads0 = constant_op.constant([0.1, 0.2], dtype=dtype)
grads1 = constant_op.constant([0.01, 0.02], dtype=dtype)
opt = adagrad_da.AdagradDAOptimizer(
3.0,
global_step,
initial_gradient_squared_accumulator_value=0.1,
l1_regularization_strength=0.0,
l2_regularization_strength=0.0)
update = opt.apply_gradients(
zip([grads0, grads1], [var0, var1]), global_step=global_step)
self.evaluate(variables.global_variables_initializer())
v0_val, v1_val = self.evaluate([var0, var1])
self.assertAllClose([0.0, 0.0], v0_val)
self.assertAllClose([0.0, 0.0], v1_val)
# Run a step of AdagradDA
update.run()
v0_val, v1_val = self.evaluate([var0, var1])
# Let g be the gradient accumulator, gg be the gradient squared
# accumulator, T be the global step, lr be the learning rate,
# and k the initial gradient squared accumulator value.
# w = \dfrac{sign(-g)*lr*|g - l1*T|_{+}}{l2*T*lr + \sqrt{k+gg})}
# For -0.1*3.0*(0.1 - 0)/(0 + sqrt(0.1 + 0.1*0.1)) = -0.904534
# similarly for others.
self.assertAllCloseAccordingToType(
np.array([-0.904534, -1.603567]), v0_val)
self.assertAllCloseAccordingToType(
np.array([-0.094821, -0.189358]), v1_val)
def testAdagradDAWithoutRegularizationBasic1(self):
self.doTestAdagradDAwithoutRegularizationBasic1()
def testResourceAdagradDAWithoutRegularizationBasic1(self):
self.doTestAdagradDAwithoutRegularizationBasic1(use_resource=True)
@test_util.run_v1_only("loss needs to be callable in v2")
def testMinimizeSparseResourceVariable(self):
for dtype in [dtypes.float32, dtypes.float64]:
with self.cached_session():
var0 = resource_variable_ops.ResourceVariable([[1.0, 2.0]], dtype=dtype)
global_step = resource_variable_ops.ResourceVariable(
0, dtype=dtypes.int64)
x = constant_op.constant([[4.0], [5.0]], dtype=dtype)
pred = math_ops.matmul(embedding_ops.embedding_lookup([var0], [0]), x)
loss = pred * pred
sgd_op = adagrad_da.AdagradDAOptimizer(
1.0, global_step).minimize(loss)
self.evaluate(variables.global_variables_initializer())
# Fetch params to validate initial values
self.assertAllCloseAccordingToType([[1.0, 2.0]], self.evaluate(var0))
# Run 1 step of sgd
sgd_op.run()
# Validate updated params
self.assertAllCloseAccordingToType([[-1, -1]],
self.evaluate(var0),
rtol=0.01)
def testAdagradDAwithoutRegularizationBasic2(self):
for dtype in [dtypes.float64, dtypes.float32]:
with ops.Graph().as_default(), self.cached_session():
global_step = variables.Variable(0, dtype=dtypes.int64)
var0 = variables.Variable([1.0, 2.0], dtype=dtype)
var1 = variables.Variable([4.0, 3.0], dtype=dtype)
grads0 = constant_op.constant([0.1, 0.2], dtype=dtype)
grads1 = constant_op.constant([0.01, 0.02], dtype=dtype)
opt = adagrad_da.AdagradDAOptimizer(
3.0,
global_step,
initial_gradient_squared_accumulator_value=0.1,
l1_regularization_strength=0.0,
l2_regularization_strength=0.0)
update = opt.apply_gradients(
zip([grads0, grads1], [var0, var1]), global_step=global_step)
self.evaluate(variables.global_variables_initializer())
v0_val, v1_val = self.evaluate([var0, var1])
self.assertAllCloseAccordingToType([1.0, 2.0], v0_val)
self.assertAllCloseAccordingToType([4.0, 3.0], v1_val)
# Run a step of AdagradDA
update.run()
v0_val, v1_val = self.evaluate([var0, var1])
self.assertAllCloseAccordingToType(
np.array([-0.904534, -1.603567]), v0_val)
self.assertAllCloseAccordingToType(
np.array([-0.094821, -0.189358]), v1_val)
def testAdagradDAWithL1(self):
for dtype in [dtypes.float64, dtypes.float32]:
with ops.Graph().as_default(), self.cached_session():
global_step = variables.Variable(0, dtype=dtypes.int64)
var0 = variables.Variable([1.0, 2.0], dtype=dtype)
var1 = variables.Variable([4.0, 3.0], dtype=dtype)
grads0 = constant_op.constant([0.1, 0.2], dtype=dtype)
grads1 = constant_op.constant([0.01, 0.02], dtype=dtype)
opt = adagrad_da.AdagradDAOptimizer(
3.0,
global_step,
initial_gradient_squared_accumulator_value=0.1,
l1_regularization_strength=0.001,
l2_regularization_strength=0.0)
update = opt.apply_gradients(
zip([grads0, grads1], [var0, var1]), global_step=global_step)
self.evaluate(variables.global_variables_initializer())
v0_val, v1_val = self.evaluate([var0, var1])
self.assertAllCloseAccordingToType([1.0, 2.0], v0_val)
self.assertAllCloseAccordingToType([4.0, 3.0], v1_val)
# Run a step of AdagradDA
update.run()
v0_val, v1_val = self.evaluate([var0, var1])
self.assertAllCloseAccordingToType(
np.array([-0.895489, -1.59555]), v0_val)
self.assertAllCloseAccordingToType(
np.array([-0.085339, -0.17989]), v1_val)
def testAdagradDAWithL1_L2(self):
for dtype in [dtypes.float64, dtypes.float32]:
with ops.Graph().as_default(), self.cached_session():
global_step = variables.Variable(0, dtype=dtypes.int64)
var0 = variables.Variable([1.0, 2.0], dtype=dtype)
var1 = variables.Variable([4.0, 3.0], dtype=dtype)
grads0 = constant_op.constant([0.1, 0.2], dtype=dtype)
grads1 = constant_op.constant([0.01, 0.02], dtype=dtype)
opt = adagrad_da.AdagradDAOptimizer(
3.0,
global_step,
initial_gradient_squared_accumulator_value=0.1,
l1_regularization_strength=0.001,
l2_regularization_strength=2.0)
update = opt.apply_gradients(
zip([grads0, grads1], [var0, var1]), global_step=global_step)
self.evaluate(variables.global_variables_initializer())
v0_val, v1_val = self.evaluate([var0, var1])
self.assertAllCloseAccordingToType([1.0, 2.0], v0_val)
self.assertAllCloseAccordingToType([4.0, 3.0], v1_val)
# Run a step of AdagradDA
update.run()
v0_val, v1_val = self.evaluate([var0, var1])
self.assertAllCloseAccordingToType(
np.array([-0.046907, -0.093659]), v0_val)
self.assertAllCloseAccordingToType(
np.array([-0.004275, -0.009023]), v1_val)
if __name__ == "__main__":
test.main()