def testAtrousFullyConvolutionalValues(self):
     """Verify dense feature extraction with atrous convolution."""
     nominal_stride = 32
     for output_stride in [4, 8, 16, 32, None]:
         with slim.arg_scope(resnet_utils.resnet_arg_scope()):
             with tf.Graph().as_default():
                 with self.test_session() as sess:
                     tf.set_random_seed(0)
                     inputs = create_test_input(2, 81, 81, 3)
                     # Dense feature extraction followed by subsampling.
                     output, _ = self._resnet_small(
                         inputs,
                         None,
                         is_training=False,
                         global_pool=False,
                         output_stride=output_stride)
                     if output_stride is None:
                         factor = 1
                     else:
                         factor = nominal_stride // output_stride
                     output = resnet_utils.subsample(output, factor)
                     # Make the two networks use the same weights.
                     tf.get_variable_scope().reuse_variables()
                     # Feature extraction at the nominal network rate.
                     expected, _ = self._resnet_small(inputs,
                                                      None,
                                                      is_training=False,
                                                      global_pool=False)
                     sess.run(tf.global_variables_initializer())
                     self.assertAllClose(output.eval(),
                                         expected.eval(),
                                         atol=1e-4,
                                         rtol=1e-4)
示例#2
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def bottleneck(inputs, depth, depth_bottleneck, stride, rate=1,
               outputs_collections=None, scope=None):
  """Bottleneck residual unit variant with BN before convolutions.

  This is the full preactivation residual unit variant proposed in [2]. See
  Fig. 1(b) of [2] for its definition. Note that we use here the bottleneck
  variant which has an extra bottleneck layer.

  When putting together two consecutive ResNet blocks that use this unit, one
  should use stride = 2 in the last unit of the first block.

  Args:
    inputs: A tensor of size [batch, height, width, channels].
    depth: The depth of the ResNet unit output.
    depth_bottleneck: The depth of the bottleneck layers.
    stride: The ResNet unit's stride. Determines the amount of downsampling of
      the units output compared to its input.
    rate: An integer, rate for atrous convolution.
    outputs_collections: Collection to add the ResNet unit output.
    scope: Optional variable_scope.

  Returns:
    The ResNet unit's output.
  """
  with tf.variable_scope(scope, 'bottleneck_v2', [inputs]) as sc:
    depth_in = slim.utils.last_dimension(inputs.get_shape(), min_rank=4)
    preact = slim.batch_norm(inputs, activation_fn=tf.nn.relu, scope='preact')
    if depth == depth_in:
      shortcut = resnet_utils.subsample(inputs, stride, 'shortcut')
    else:
      shortcut = slim.conv2d(preact, depth, [1, 1], stride=stride,
                             normalizer_fn=None, activation_fn=None,
                             scope='shortcut')

    residual = slim.conv2d(preact, depth_bottleneck, [1, 1], stride=1,
                           scope='conv1')
    residual = resnet_utils.conv2d_same(residual, depth_bottleneck, 3, stride,
                                        rate=rate, scope='conv2')
    residual = slim.conv2d(residual, depth, [1, 1], stride=1,
                           normalizer_fn=None, activation_fn=None,
                           scope='conv3')

    output = shortcut + residual

    return slim.utils.collect_named_outputs(outputs_collections,
                                            sc.name,
                                            output)
    def testAtrousValuesBottleneck(self):
        """Verify the values of dense feature extraction by atrous convolution.

    Make sure that dense feature extraction by stack_blocks_dense() followed by
    subsampling gives identical results to feature extraction at the nominal
    network output stride using the simple self._stack_blocks_nondense() above.
    """
        block = resnet_v2.resnet_v2_block
        blocks = [
            block('block1', base_depth=1, num_units=2, stride=2),
            block('block2', base_depth=2, num_units=2, stride=2),
            block('block3', base_depth=4, num_units=2, stride=2),
            block('block4', base_depth=8, num_units=2, stride=1),
        ]
        nominal_stride = 8

        # Test both odd and even input dimensions.
        height = 30
        width = 31
        with slim.arg_scope(resnet_utils.resnet_arg_scope()):
            with slim.arg_scope([slim.batch_norm], is_training=False):
                for output_stride in [1, 2, 4, 8, None]:
                    with tf.Graph().as_default():
                        with self.test_session() as sess:
                            tf.set_random_seed(0)
                            inputs = create_test_input(1, height, width, 3)
                            # Dense feature extraction followed by subsampling.
                            output = resnet_utils.stack_blocks_dense(
                                inputs, blocks, output_stride)
                            if output_stride is None:
                                factor = 1
                            else:
                                factor = nominal_stride // output_stride

                            output = resnet_utils.subsample(output, factor)
                            # Make the two networks use the same weights.
                            tf.get_variable_scope().reuse_variables()
                            # Feature extraction at the nominal network rate.
                            expected = self._stack_blocks_nondense(
                                inputs, blocks)
                            sess.run(tf.global_variables_initializer())
                            output, expected = sess.run([output, expected])
                            self.assertAllClose(output,
                                                expected,
                                                atol=1e-4,
                                                rtol=1e-4)
    def testConv2DSameOdd(self):
        n, n2 = 5, 3

        # Input image.
        x = create_test_input(1, n, n, 1)

        # Convolution kernel.
        w = create_test_input(1, 3, 3, 1)
        w = tf.reshape(w, [3, 3, 1, 1])

        tf.get_variable('Conv/weights', initializer=w)
        tf.get_variable('Conv/biases', initializer=tf.zeros([1]))
        tf.get_variable_scope().reuse_variables()

        y1 = slim.conv2d(x, 1, [3, 3], stride=1, scope='Conv')
        y1_expected = tf.to_float([[14, 28, 43, 58, 34], [28, 48, 66, 84, 46],
                                   [43, 66, 84, 102,
                                    55], [58, 84, 102, 120, 64],
                                   [34, 46, 55, 64, 30]])
        y1_expected = tf.reshape(y1_expected, [1, n, n, 1])

        y2 = resnet_utils.subsample(y1, 2)
        y2_expected = tf.to_float([[14, 43, 34], [43, 84, 55], [34, 55, 30]])
        y2_expected = tf.reshape(y2_expected, [1, n2, n2, 1])

        y3 = resnet_utils.conv2d_same(x, 1, 3, stride=2, scope='Conv')
        y3_expected = y2_expected

        y4 = slim.conv2d(x, 1, [3, 3], stride=2, scope='Conv')
        y4_expected = y2_expected

        with self.test_session() as sess:
            sess.run(tf.global_variables_initializer())
            self.assertAllClose(y1.eval(), y1_expected.eval())
            self.assertAllClose(y2.eval(), y2_expected.eval())
            self.assertAllClose(y3.eval(), y3_expected.eval())
            self.assertAllClose(y4.eval(), y4_expected.eval())
示例#5
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def bottleneck(inputs,
               depth,
               depth_bottleneck,
               stride,
               rate=1,
               outputs_collections=None,
               scope=None,
               use_bounded_activations=False):
    """Bottleneck residual unit variant with BN after convolutions.

    This is the original residual unit proposed in [1]. See Fig. 1(a) of [2] for
    its definition. Note that we use here the bottleneck variant which has an
    extra bottleneck layer.

    When putting together two consecutive ResNet blocks that use this unit, one
    should use stride = 2 in the last unit of the first block.

    Args:
      inputs: A tensor of size [batch, height, width, channels].
      depth: The depth of the ResNet unit output.
      depth_bottleneck: The depth of the bottleneck layers.
      stride: The ResNet unit's stride. Determines the amount of downsampling of
        the units output compared to its input.
      rate: An integer, rate for atrous convolution.
      outputs_collections: Collection to add the ResNet unit output.
      scope: Optional variable_scope.
      use_bounded_activations: Whether or not to use bounded activations. Bounded
        activations better lend themselves to quantized inference.

    Returns:
      The ResNet unit's output.
    """
    with tf.variable_scope(scope, 'bottleneck_v1', [inputs]) as sc:
        depth_in = slim.utils.last_dimension(inputs.get_shape(), min_rank=4)
        if depth == depth_in:
            shortcut = resnet_utils.subsample(inputs, stride, 'shortcut')
        else:
            shortcut = slim.conv2d(
                inputs,
                depth, [1, 1],
                stride=stride,
                activation_fn=tf.nn.relu6 if use_bounded_activations else None,
                scope='shortcut')

        residual = slim.conv2d(inputs,
                               depth_bottleneck, [1, 1],
                               stride=1,
                               scope='conv1')
        residual = resnet_utils.conv2d_same(residual,
                                            depth_bottleneck,
                                            3,
                                            stride,
                                            rate=rate,
                                            scope='conv2')
        residual = slim.conv2d(residual,
                               depth, [1, 1],
                               stride=1,
                               activation_fn=None,
                               scope='conv3')

        if use_bounded_activations:
            # Use clip_by_value to simulate bandpass activation.
            residual = tf.clip_by_value(residual, -6.0, 6.0)
            output = tf.nn.relu6(shortcut + residual)
        else:
            output = tf.nn.relu(shortcut + residual)

        return slim.utils.collect_named_outputs(outputs_collections, sc.name,
                                                output)
 def testSubsampleFourByFour(self):
     x = tf.reshape(tf.to_float(tf.range(16)), [1, 4, 4, 1])
     x = resnet_utils.subsample(x, 2)
     expected = tf.reshape(tf.constant([0, 2, 8, 10]), [1, 2, 2, 1])
     with self.test_session():
         self.assertAllClose(x.eval(), expected.eval())
 def testSubsampleThreeByThree(self):
     x = tf.reshape(tf.to_float(tf.range(9)), [1, 3, 3, 1])
     x = resnet_utils.subsample(x, 2)
     expected = tf.reshape(tf.constant([0, 2, 6, 8]), [1, 2, 2, 1])
     with self.test_session():
         self.assertAllClose(x.eval(), expected.eval())
    def testStridingLastUnitVsSubsampleBlockEnd(self):
        """Compares subsampling at the block's last unit or block's end.

    Makes sure that the final output is the same when we use a stride at the
    last unit of a block vs. we subsample activations at the end of a block.
    """
        block = resnet_v1.resnet_v1_block

        blocks = [
            block('block1', base_depth=1, num_units=2, stride=2),
            block('block2', base_depth=2, num_units=2, stride=2),
            block('block3', base_depth=4, num_units=2, stride=2),
            block('block4', base_depth=8, num_units=2, stride=1),
        ]

        # Test both odd and even input dimensions.
        height = 30
        width = 31
        with slim.arg_scope(resnet_utils.resnet_arg_scope()):
            with slim.arg_scope([slim.batch_norm], is_training=False):
                for output_stride in [1, 2, 4, 8, None]:
                    with tf.Graph().as_default():
                        with self.test_session() as sess:
                            tf.set_random_seed(0)
                            inputs = create_test_input(1, height, width, 3)

                            # Subsampling at the last unit of the block.
                            output = resnet_utils.stack_blocks_dense(
                                inputs,
                                blocks,
                                output_stride,
                                store_non_strided_activations=False,
                                outputs_collections='output')
                            output_end_points = slim.utils.convert_collection_to_dict(
                                'output')

                            # Make the two networks use the same weights.
                            tf.get_variable_scope().reuse_variables()

                            # Subsample activations at the end of the blocks.
                            expected = resnet_utils.stack_blocks_dense(
                                inputs,
                                blocks,
                                output_stride,
                                store_non_strided_activations=True,
                                outputs_collections='expected')
                            expected_end_points = slim.utils.convert_collection_to_dict(
                                'expected')

                            sess.run(tf.global_variables_initializer())

                            # Make sure that the final output is the same.
                            output, expected = sess.run([output, expected])
                            self.assertAllClose(output,
                                                expected,
                                                atol=1e-4,
                                                rtol=1e-4)

                            # Make sure that intermediate block activations in
                            # output_end_points are subsampled versions of the corresponding
                            # ones in expected_end_points.
                            for i, block in enumerate(blocks[:-1:]):
                                output = output_end_points[block.scope]
                                expected = expected_end_points[block.scope]
                                atrous_activated = (output_stride is not None
                                                    and 2**i >= output_stride)
                                if not atrous_activated:
                                    expected = resnet_utils.subsample(
                                        expected, 2)
                                output, expected = sess.run([output, expected])
                                self.assertAllClose(output,
                                                    expected,
                                                    atol=1e-4,
                                                    rtol=1e-4)