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# Copyright 2015 Google Inc. 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 slice op."""

from __future__ import absolute_import

from __future__ import division

from __future__ import print_function

import tensorflow.python.platform

import numpy as np

from six.moves import xrange # pylint: disable=redefined-builtin

import tensorflow as tf

class SliceTest(tf.test.TestCase):

def _testEmpty(self, use_gpu):

inp = np.random.rand(4, 4).astype("f")

for k in xrange(4):

with self.test_session(use_gpu=use_gpu):

a = tf.constant(inp, shape=[4, 4], dtype=tf.float32)

slice_t = a[2, k:k]

slice_val = slice_t.eval()

self.assertAllEqual(slice_val, inp[2, k:k])

def testEmptyAll(self):

self._testEmpty(use_gpu=False)

self._testEmpty(use_gpu=True)

def _testInt32(self, use_gpu):

inp = np.random.rand(4, 4).astype("i")

for k in xrange(4):

with self.test_session(use_gpu=use_gpu):

a = tf.constant(inp, shape=[4, 4], dtype=tf.int32)

slice_t = a[2, k:k]

slice_val = slice_t.eval()

self.assertAllEqual(slice_val, inp[2, k:k])

def testInt32(self):

self._testEmpty(use_gpu=False)

self._testEmpty(use_gpu=True)

def _testSelectAll(self, use_gpu):

with self.test_session(use_gpu=use_gpu):

inp = np.random.rand(4, 4, 4, 4).astype("f")

a = tf.constant(inp, shape=[4, 4, 4, 4],

dtype=tf.float32)

slice_explicit_t = tf.slice(a, [0, 0, 0, 0], [-1, -1, -1, -1])

slice_implicit_t = a[:, :, :, :]

self.assertAllEqual(inp, slice_explicit_t.eval())

self.assertAllEqual(inp, slice_implicit_t.eval())

self.assertEqual(inp.shape, slice_explicit_t.get_shape())

self.assertEqual(inp.shape, slice_implicit_t.get_shape())

def testSelectAll(self):

for _ in range(10):

self._testSelectAll(use_gpu=False)

self._testSelectAll(use_gpu=True)

def _testSingleDimension(self, use_gpu):

with self.test_session(use_gpu=use_gpu):

inp = np.random.rand(10).astype("f")

a = tf.constant(inp, shape=[10], dtype=tf.float32)

hi = np.random.random_integers(0, 9)

scalar_t = a[hi]

scalar_val = scalar_t.eval()

self.assertAllEqual(scalar_val, inp[hi])

lo = np.random.random_integers(0, hi)

slice_t = a[lo:hi]

slice_val = slice_t.eval()

self.assertAllEqual(slice_val, inp[lo:hi])

def testSingleDimension(self):

for _ in range(10):

self._testSingleDimension(use_gpu=False)

self._testSingleDimension(use_gpu=True)

def _testSliceMatrixDim0(self, x, begin, size, use_gpu):

with self.test_session(use_gpu=use_gpu):

tf_ans = tf.slice(x, [begin, 0], [size, x.shape[1]]).eval()

np_ans = x[begin:begin+size, :]

self.assertAllEqual(tf_ans, np_ans)

def testSliceMatrixDim0(self):

for use_gpu in [False, True]:

x = np.random.rand(8, 4).astype("f")

self._testSliceMatrixDim0(x, 1, 2, use_gpu)

self._testSliceMatrixDim0(x, 3, 3, use_gpu)

y = np.random.rand(8, 7).astype("f") # 7 * sizeof(float) is not aligned

self._testSliceMatrixDim0(y, 1, 2, use_gpu)

self._testSliceMatrixDim0(y, 3, 3, use_gpu)

def _testIndexAndSlice(self, use_gpu):

with self.test_session(use_gpu=use_gpu):

inp = np.random.rand(4, 4).astype("f")

a = tf.constant(inp, shape=[4, 4], dtype=tf.float32)

x, y = np.random.random_integers(0, 3, size=2).tolist()

slice_t = a[x, 0:y]

slice_val = slice_t.eval()

self.assertAllEqual(slice_val, inp[x, 0:y])

def testSingleElementAll(self):

for _ in range(10):

self._testIndexAndSlice(use_gpu=False)

self._testIndexAndSlice(use_gpu=True)

def _testSimple(self, use_gpu):

with self.test_session(use_gpu=use_gpu) as sess:

inp = np.random.rand(4, 4).astype("f")

a = tf.constant([float(x) for x in inp.ravel(order="C")],

shape=[4, 4], dtype=tf.float32)

slice_t = tf.slice(a, [0, 0], [2, 2])

slice2_t = a[:2, :2]

slice_val, slice2_val = sess.run([slice_t, slice2_t])

self.assertAllEqual(slice_val, inp[:2, :2])

self.assertAllEqual(slice2_val, inp[:2, :2])

self.assertEqual(slice_val.shape, slice_t.get_shape())

self.assertEqual(slice2_val.shape, slice2_t.get_shape())

def testSimpleAll(self):

self._testSimple(use_gpu=False)

self._testSimple(use_gpu=True)

def _testComplex(self, use_gpu):

with self.test_session(use_gpu=use_gpu):

inp = np.random.rand(4, 10, 10, 4).astype("f")

a = tf.constant(inp, dtype=tf.float32)

x = np.random.random_integers(0, 9)

z = np.random.random_integers(0, 9)

y = np.random.random_integers(0, z)

slice_t = a[:, x, y:z, :]

self.assertAllEqual(slice_t.eval(), inp[:, x, y:z, :])

def testComplex(self):

for _ in range(10):

self._testComplex(use_gpu=False)

self._testComplex(use_gpu=True)

def _RunAndVerifyResult(self, use_gpu):

# Random dims of rank 5

input_shape = np.random.randint(0, 20, size=5)

inp = np.random.rand(*input_shape).astype("f")

with self.test_session(use_gpu=use_gpu) as sess:

a = tf.constant([float(x) for x in inp.ravel(order="C")],

shape=input_shape, dtype=tf.float32)

indices = [0 if x == 0 else np.random.randint(x) for x in input_shape]

sizes = [np.random.randint(0, input_shape[i] - indices[i] + 1)

for i in range(5)]

slice_t = tf.slice(a, indices, sizes)

slice2_t = a[indices[0]:indices[0]+sizes[0],

indices[1]:indices[1]+sizes[1],

indices[2]:indices[2]+sizes[2],

indices[3]:indices[3]+sizes[3],

indices[4]:indices[4]+sizes[4]]

slice_val, slice2_val = sess.run([slice_t, slice2_t])

expected_val = inp[indices[0]:indices[0]+sizes[0],

indices[1]:indices[1]+sizes[1],

indices[2]:indices[2]+sizes[2],

indices[3]:indices[3]+sizes[3],

indices[4]:indices[4]+sizes[4]]

self.assertAllEqual(slice_val, expected_val)

self.assertAllEqual(slice2_val, expected_val)

self.assertEqual(expected_val.shape, slice_t.get_shape())

self.assertEqual(expected_val.shape, slice2_t.get_shape())

def testRandom(self):

for _ in range(10):

self._RunAndVerifyResult(use_gpu=False)

self._RunAndVerifyResult(use_gpu=True)

def _testGradientSlice(self, input_shape, slice_begin, slice_size, use_gpu):

with self.test_session(use_gpu=use_gpu):

num_inputs = np.prod(input_shape)

num_grads = np.prod(slice_size)

inp = np.random.rand(num_inputs).astype("f").reshape(input_shape)

a = tf.constant([float(x) for x in inp.ravel(order="C")],

shape=input_shape, dtype=tf.float32)

slice_t = tf.slice(a, slice_begin, slice_size)

grads = np.random.rand(num_grads).astype("f").reshape(slice_size)

grad_tensor = tf.constant(grads)

grad = tf.gradients(slice_t, [a], grad_tensor)[0]

result = grad.eval()

# Create a zero tensor of the input shape ane place

# the grads into the right location to compare against TensorFlow.

np_ans = np.zeros(input_shape)

slices = []

for i in xrange(len(input_shape)):

slices.append(slice(slice_begin[i], slice_begin[i] + slice_size[i]))

np_ans[slices] = grads

self.assertAllClose(np_ans, result)

def _testGradientVariableSize(self, use_gpu):

with self.test_session(use_gpu=use_gpu):

inp = tf.constant([1.0, 2.0, 3.0], name="in")

out = tf.slice(inp, [1], [-1])

grad_actual = tf.gradients(out, inp)[0].eval()

self.assertAllClose([0., 1., 1.], grad_actual)

def _testGradientsSimple(self, use_gpu):

# Slice the middle square out of a 4x4 input

self._testGradientSlice([4, 4], [1, 1], [2, 2], use_gpu)

# Slice the upper left square out of a 4x4 input

self._testGradientSlice([4, 4], [0, 0], [2, 2], use_gpu)

# Slice a non-square input starting from (2,1)

self._testGradientSlice([4, 4], [2, 1], [1, 2], use_gpu)

# Slice a 3D tensor

self._testGradientSlice([3, 3, 3], [0, 1, 0], [2, 1, 1], use_gpu)

# Use -1 as a slice dimension.

self._testGradientVariableSize(use_gpu)

def testGradientsAll(self):

self._testGradientsSimple(use_gpu=False)

self._testGradientsSimple(use_gpu=True)

def testNotIterable(self):

# NOTE(mrry): If we register __getitem__ as an overloaded

# operator, Python will valiantly attempt to iterate over the

# Tensor from 0 to infinity. This test ensures that this

# unintended behavior is prevented.

c = tf.constant(5.0)

with self.assertRaisesWithPredicateMatch(

TypeError,

lambda e: "'Tensor' object is not iterable" in str(e)):

for _ in c:

pass

if __name__ == "__main__":

tf.test.main()