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model_lib.py
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model_lib.py
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# Copyright 2017 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.
# ==============================================================================
r"""Constructs model, inputs, and training environment."""
from __future__ import absolute_import
from __future__ import division
from __future__ import print_function
import copy
import functools
import os
import tensorflow as tf
from object_detection import eval_util
from object_detection import exporter as exporter_lib
from object_detection import inputs
from object_detection.builders import graph_rewriter_builder
from object_detection.builders import model_builder
from object_detection.builders import optimizer_builder
from object_detection.core import standard_fields as fields
from object_detection.utils import config_util
from object_detection.utils import label_map_util
from object_detection.utils import ops
from object_detection.utils import shape_utils
from object_detection.utils import variables_helper
from object_detection.utils import visualization_utils as vis_utils
# A map of names to methods that help build the model.
MODEL_BUILD_UTIL_MAP = {
'get_configs_from_pipeline_file':
config_util.get_configs_from_pipeline_file,
'create_pipeline_proto_from_configs':
config_util.create_pipeline_proto_from_configs,
'merge_external_params_with_configs':
config_util.merge_external_params_with_configs,
'create_train_input_fn':
inputs.create_train_input_fn,
'create_eval_input_fn':
inputs.create_eval_input_fn,
'create_predict_input_fn':
inputs.create_predict_input_fn,
'detection_model_fn_base': model_builder.build,
}
def _prepare_groundtruth_for_eval(detection_model, class_agnostic,
max_number_of_boxes):
"""Extracts groundtruth data from detection_model and prepares it for eval.
Args:
detection_model: A `DetectionModel` object.
class_agnostic: Whether the detections are class_agnostic.
max_number_of_boxes: Max number of groundtruth boxes.
Returns:
A tuple of:
groundtruth: Dictionary with the following fields:
'groundtruth_boxes': [batch_size, num_boxes, 4] float32 tensor of boxes,
in normalized coordinates.
'groundtruth_classes': [batch_size, num_boxes] int64 tensor of 1-indexed
classes.
'groundtruth_masks': 4D float32 tensor of instance masks (if provided in
groundtruth)
'groundtruth_is_crowd': [batch_size, num_boxes] bool tensor indicating
is_crowd annotations (if provided in groundtruth).
'num_groundtruth_boxes': [batch_size] tensor containing the maximum number
of groundtruth boxes per image..
class_agnostic: Boolean indicating whether detections are class agnostic.
"""
input_data_fields = fields.InputDataFields()
groundtruth_boxes = tf.stack(
detection_model.groundtruth_lists(fields.BoxListFields.boxes))
groundtruth_boxes_shape = tf.shape(groundtruth_boxes)
# For class-agnostic models, groundtruth one-hot encodings collapse to all
# ones.
if class_agnostic:
groundtruth_classes_one_hot = tf.ones(
[groundtruth_boxes_shape[0], groundtruth_boxes_shape[1], 1])
else:
groundtruth_classes_one_hot = tf.stack(
detection_model.groundtruth_lists(fields.BoxListFields.classes))
label_id_offset = 1 # Applying label id offset (b/63711816)
groundtruth_classes = (
tf.argmax(groundtruth_classes_one_hot, axis=2) + label_id_offset)
groundtruth = {
input_data_fields.groundtruth_boxes: groundtruth_boxes,
input_data_fields.groundtruth_classes: groundtruth_classes
}
if detection_model.groundtruth_has_field(fields.BoxListFields.masks):
groundtruth[input_data_fields.groundtruth_instance_masks] = tf.stack(
detection_model.groundtruth_lists(fields.BoxListFields.masks))
if detection_model.groundtruth_has_field(fields.BoxListFields.is_crowd):
groundtruth[input_data_fields.groundtruth_is_crowd] = tf.stack(
detection_model.groundtruth_lists(fields.BoxListFields.is_crowd))
groundtruth[input_data_fields.num_groundtruth_boxes] = (
tf.tile([max_number_of_boxes], multiples=[groundtruth_boxes_shape[0]]))
return groundtruth
def unstack_batch(tensor_dict, unpad_groundtruth_tensors=True):
"""Unstacks all tensors in `tensor_dict` along 0th dimension.
Unstacks tensor from the tensor dict along 0th dimension and returns a
tensor_dict containing values that are lists of unstacked, unpadded tensors.
Tensors in the `tensor_dict` are expected to be of one of the three shapes:
1. [batch_size]
2. [batch_size, height, width, channels]
3. [batch_size, num_boxes, d1, d2, ... dn]
When unpad_groundtruth_tensors is set to true, unstacked tensors of form 3
above are sliced along the `num_boxes` dimension using the value in tensor
field.InputDataFields.num_groundtruth_boxes.
Note that this function has a static list of input data fields and has to be
kept in sync with the InputDataFields defined in core/standard_fields.py
Args:
tensor_dict: A dictionary of batched groundtruth tensors.
unpad_groundtruth_tensors: Whether to remove padding along `num_boxes`
dimension of the groundtruth tensors.
Returns:
A dictionary where the keys are from fields.InputDataFields and values are
a list of unstacked (optionally unpadded) tensors.
Raises:
ValueError: If unpad_tensors is True and `tensor_dict` does not contain
`num_groundtruth_boxes` tensor.
"""
unbatched_tensor_dict = {
key: tf.unstack(tensor) for key, tensor in tensor_dict.items()
}
if unpad_groundtruth_tensors:
if (fields.InputDataFields.num_groundtruth_boxes not in
unbatched_tensor_dict):
raise ValueError('`num_groundtruth_boxes` not found in tensor_dict. '
'Keys available: {}'.format(
unbatched_tensor_dict.keys()))
unbatched_unpadded_tensor_dict = {}
unpad_keys = set([
# List of input data fields that are padded along the num_boxes
# dimension. This list has to be kept in sync with InputDataFields in
# standard_fields.py.
fields.InputDataFields.groundtruth_instance_masks,
fields.InputDataFields.groundtruth_classes,
fields.InputDataFields.groundtruth_boxes,
fields.InputDataFields.groundtruth_keypoints,
fields.InputDataFields.groundtruth_group_of,
fields.InputDataFields.groundtruth_difficult,
fields.InputDataFields.groundtruth_is_crowd,
fields.InputDataFields.groundtruth_area,
fields.InputDataFields.groundtruth_weights
]).intersection(set(unbatched_tensor_dict.keys()))
for key in unpad_keys:
unpadded_tensor_list = []
for num_gt, padded_tensor in zip(
unbatched_tensor_dict[fields.InputDataFields.num_groundtruth_boxes],
unbatched_tensor_dict[key]):
tensor_shape = shape_utils.combined_static_and_dynamic_shape(
padded_tensor)
slice_begin = tf.zeros([len(tensor_shape)], dtype=tf.int32)
slice_size = tf.stack(
[num_gt] + [-1 if dim is None else dim for dim in tensor_shape[1:]])
unpadded_tensor = tf.slice(padded_tensor, slice_begin, slice_size)
unpadded_tensor_list.append(unpadded_tensor)
unbatched_unpadded_tensor_dict[key] = unpadded_tensor_list
unbatched_tensor_dict.update(unbatched_unpadded_tensor_dict)
return unbatched_tensor_dict
def provide_groundtruth(model, labels):
"""Provides the labels to a model as groundtruth.
This helper function extracts the corresponding boxes, classes,
keypoints, weights, masks, etc. from the labels, and provides it
as groundtruth to the models.
Args:
model: The detection model to provide groundtruth to.
labels: The labels for the training or evaluation inputs.
"""
gt_boxes_list = labels[fields.InputDataFields.groundtruth_boxes]
gt_classes_list = labels[fields.InputDataFields.groundtruth_classes]
gt_masks_list = None
if fields.InputDataFields.groundtruth_instance_masks in labels:
gt_masks_list = labels[
fields.InputDataFields.groundtruth_instance_masks]
gt_keypoints_list = None
if fields.InputDataFields.groundtruth_keypoints in labels:
gt_keypoints_list = labels[fields.InputDataFields.groundtruth_keypoints]
gt_weights_list = None
if fields.InputDataFields.groundtruth_weights in labels:
gt_weights_list = labels[fields.InputDataFields.groundtruth_weights]
gt_confidences_list = None
if fields.InputDataFields.groundtruth_confidences in labels:
gt_confidences_list = labels[
fields.InputDataFields.groundtruth_confidences]
gt_is_crowd_list = None
if fields.InputDataFields.groundtruth_is_crowd in labels:
gt_is_crowd_list = labels[fields.InputDataFields.groundtruth_is_crowd]
model.provide_groundtruth(
groundtruth_boxes_list=gt_boxes_list,
groundtruth_classes_list=gt_classes_list,
groundtruth_confidences_list=gt_confidences_list,
groundtruth_masks_list=gt_masks_list,
groundtruth_keypoints_list=gt_keypoints_list,
groundtruth_weights_list=gt_weights_list,
groundtruth_is_crowd_list=gt_is_crowd_list)
def create_model_fn(detection_model_fn, configs, hparams, use_tpu=False,
postprocess_on_cpu=False):
"""Creates a model function for `Estimator`.
Args:
detection_model_fn: Function that returns a `DetectionModel` instance.
configs: Dictionary of pipeline config objects.
hparams: `HParams` object.
use_tpu: Boolean indicating whether model should be constructed for
use on TPU.
postprocess_on_cpu: When use_tpu and postprocess_on_cpu is true, postprocess
is scheduled on the host cpu.
Returns:
`model_fn` for `Estimator`.
"""
train_config = configs['train_config']
eval_input_config = configs['eval_input_config']
eval_config = configs['eval_config']
def model_fn(features, labels, mode, params=None):
"""Constructs the object detection model.
Args:
features: Dictionary of feature tensors, returned from `input_fn`.
labels: Dictionary of groundtruth tensors if mode is TRAIN or EVAL,
otherwise None.
mode: Mode key from tf.estimator.ModeKeys.
params: Parameter dictionary passed from the estimator.
Returns:
An `EstimatorSpec` that encapsulates the model and its serving
configurations.
"""
params = params or {}
total_loss, train_op, detections, export_outputs = None, None, None, None
is_training = mode == tf.estimator.ModeKeys.TRAIN
# Make sure to set the Keras learning phase. True during training,
# False for inference.
tf.keras.backend.set_learning_phase(is_training)
detection_model = detection_model_fn(
is_training=is_training, add_summaries=(not use_tpu))
scaffold_fn = None
if mode == tf.estimator.ModeKeys.TRAIN:
labels = unstack_batch(
labels,
unpad_groundtruth_tensors=train_config.unpad_groundtruth_tensors)
elif mode == tf.estimator.ModeKeys.EVAL:
# For evaling on train data, it is necessary to check whether groundtruth
# must be unpadded.
boxes_shape = (
labels[fields.InputDataFields.groundtruth_boxes].get_shape()
.as_list())
unpad_groundtruth_tensors = boxes_shape[1] is not None and not use_tpu
labels = unstack_batch(
labels, unpad_groundtruth_tensors=unpad_groundtruth_tensors)
if mode in (tf.estimator.ModeKeys.TRAIN, tf.estimator.ModeKeys.EVAL):
provide_groundtruth(detection_model, labels)
preprocessed_images = features[fields.InputDataFields.image]
if use_tpu and train_config.use_bfloat16:
with tf.contrib.tpu.bfloat16_scope():
prediction_dict = detection_model.predict(
preprocessed_images,
features[fields.InputDataFields.true_image_shape])
prediction_dict = ops.bfloat16_to_float32_nested(prediction_dict)
else:
prediction_dict = detection_model.predict(
preprocessed_images,
features[fields.InputDataFields.true_image_shape])
def postprocess_wrapper(args):
return detection_model.postprocess(args[0], args[1])
if mode in (tf.estimator.ModeKeys.EVAL, tf.estimator.ModeKeys.PREDICT):
if use_tpu and postprocess_on_cpu:
detections = tf.contrib.tpu.outside_compilation(
postprocess_wrapper,
(prediction_dict,
features[fields.InputDataFields.true_image_shape]))
else:
detections = postprocess_wrapper((
prediction_dict,
features[fields.InputDataFields.true_image_shape]))
if mode == tf.estimator.ModeKeys.TRAIN:
if train_config.fine_tune_checkpoint and hparams.load_pretrained:
if not train_config.fine_tune_checkpoint_type:
# train_config.from_detection_checkpoint field is deprecated. For
# backward compatibility, set train_config.fine_tune_checkpoint_type
# based on train_config.from_detection_checkpoint.
if train_config.from_detection_checkpoint:
train_config.fine_tune_checkpoint_type = 'detection'
else:
train_config.fine_tune_checkpoint_type = 'classification'
asg_map = detection_model.restore_map(
fine_tune_checkpoint_type=train_config.fine_tune_checkpoint_type,
load_all_detection_checkpoint_vars=(
train_config.load_all_detection_checkpoint_vars))
available_var_map = (
variables_helper.get_variables_available_in_checkpoint(
asg_map,
train_config.fine_tune_checkpoint,
include_global_step=False))
if use_tpu:
def tpu_scaffold():
tf.train.init_from_checkpoint(train_config.fine_tune_checkpoint,
available_var_map)
return tf.train.Scaffold()
scaffold_fn = tpu_scaffold
else:
tf.train.init_from_checkpoint(train_config.fine_tune_checkpoint,
available_var_map)
if mode in (tf.estimator.ModeKeys.TRAIN, tf.estimator.ModeKeys.EVAL):
losses_dict = detection_model.loss(
prediction_dict, features[fields.InputDataFields.true_image_shape])
losses = [loss_tensor for loss_tensor in losses_dict.values()]
if train_config.add_regularization_loss:
regularization_losses = detection_model.regularization_losses()
if use_tpu and train_config.use_bfloat16:
regularization_losses = ops.bfloat16_to_float32_nested(
regularization_losses)
if regularization_losses:
regularization_loss = tf.add_n(
regularization_losses, name='regularization_loss')
losses.append(regularization_loss)
losses_dict['Loss/regularization_loss'] = regularization_loss
total_loss = tf.add_n(losses, name='total_loss')
losses_dict['Loss/total_loss'] = total_loss
if 'graph_rewriter_config' in configs:
graph_rewriter_fn = graph_rewriter_builder.build(
configs['graph_rewriter_config'], is_training=is_training)
graph_rewriter_fn()
# TODO(rathodv): Stop creating optimizer summary vars in EVAL mode once we
# can write learning rate summaries on TPU without host calls.
global_step = tf.train.get_or_create_global_step()
training_optimizer, optimizer_summary_vars = optimizer_builder.build(
train_config.optimizer)
if mode == tf.estimator.ModeKeys.TRAIN:
if use_tpu:
training_optimizer = tf.contrib.tpu.CrossShardOptimizer(
training_optimizer)
# Optionally freeze some layers by setting their gradients to be zero.
trainable_variables = None
include_variables = (
train_config.update_trainable_variables
if train_config.update_trainable_variables else None)
exclude_variables = (
train_config.freeze_variables
if train_config.freeze_variables else None)
trainable_variables = tf.contrib.framework.filter_variables(
tf.trainable_variables(),
include_patterns=include_variables,
exclude_patterns=exclude_variables)
clip_gradients_value = None
if train_config.gradient_clipping_by_norm > 0:
clip_gradients_value = train_config.gradient_clipping_by_norm
if not use_tpu:
for var in optimizer_summary_vars:
tf.summary.scalar(var.op.name, var)
summaries = [] if use_tpu else None
if train_config.summarize_gradients:
summaries = ['gradients', 'gradient_norm', 'global_gradient_norm']
train_op = tf.contrib.layers.optimize_loss(
loss=total_loss,
global_step=global_step,
learning_rate=None,
clip_gradients=clip_gradients_value,
optimizer=training_optimizer,
update_ops=detection_model.updates(),
variables=trainable_variables,
summaries=summaries,
name='') # Preventing scope prefix on all variables.
if mode == tf.estimator.ModeKeys.PREDICT:
exported_output = exporter_lib.add_output_tensor_nodes(detections)
export_outputs = {
tf.saved_model.signature_constants.PREDICT_METHOD_NAME:
tf.estimator.export.PredictOutput(exported_output)
}
eval_metric_ops = None
scaffold = None
if mode == tf.estimator.ModeKeys.EVAL:
class_agnostic = (
fields.DetectionResultFields.detection_classes not in detections)
groundtruth = _prepare_groundtruth_for_eval(
detection_model, class_agnostic,
eval_input_config.max_number_of_boxes)
use_original_images = fields.InputDataFields.original_image in features
if use_original_images:
eval_images = features[fields.InputDataFields.original_image]
true_image_shapes = tf.slice(
features[fields.InputDataFields.true_image_shape], [0, 0], [-1, 3])
original_image_spatial_shapes = features[fields.InputDataFields
.original_image_spatial_shape]
else:
eval_images = features[fields.InputDataFields.image]
true_image_shapes = None
original_image_spatial_shapes = None
eval_dict = eval_util.result_dict_for_batched_example(
eval_images,
features[inputs.HASH_KEY],
detections,
groundtruth,
class_agnostic=class_agnostic,
scale_to_absolute=True,
original_image_spatial_shapes=original_image_spatial_shapes,
true_image_shapes=true_image_shapes)
if class_agnostic:
category_index = label_map_util.create_class_agnostic_category_index()
else:
category_index = label_map_util.create_category_index_from_labelmap(
eval_input_config.label_map_path)
vis_metric_ops = None
if not use_tpu and use_original_images:
eval_metric_op_vis = vis_utils.VisualizeSingleFrameDetections(
category_index,
max_examples_to_draw=eval_config.num_visualizations,
max_boxes_to_draw=eval_config.max_num_boxes_to_visualize,
min_score_thresh=eval_config.min_score_threshold,
use_normalized_coordinates=False)
vis_metric_ops = eval_metric_op_vis.get_estimator_eval_metric_ops(
eval_dict)
# Eval metrics on a single example.
eval_metric_ops = eval_util.get_eval_metric_ops_for_evaluators(
eval_config, list(category_index.values()), eval_dict)
for loss_key, loss_tensor in iter(losses_dict.items()):
eval_metric_ops[loss_key] = tf.metrics.mean(loss_tensor)
for var in optimizer_summary_vars:
eval_metric_ops[var.op.name] = (var, tf.no_op())
if vis_metric_ops is not None:
eval_metric_ops.update(vis_metric_ops)
eval_metric_ops = {str(k): v for k, v in eval_metric_ops.items()}
if eval_config.use_moving_averages:
variable_averages = tf.train.ExponentialMovingAverage(0.0)
variables_to_restore = variable_averages.variables_to_restore()
keep_checkpoint_every_n_hours = (
train_config.keep_checkpoint_every_n_hours)
saver = tf.train.Saver(
variables_to_restore,
keep_checkpoint_every_n_hours=keep_checkpoint_every_n_hours)
scaffold = tf.train.Scaffold(saver=saver)
# EVAL executes on CPU, so use regular non-TPU EstimatorSpec.
if use_tpu and mode != tf.estimator.ModeKeys.EVAL:
return tf.contrib.tpu.TPUEstimatorSpec(
mode=mode,
scaffold_fn=scaffold_fn,
predictions=detections,
loss=total_loss,
train_op=train_op,
eval_metrics=eval_metric_ops,
export_outputs=export_outputs)
else:
if scaffold is None:
keep_checkpoint_every_n_hours = (
train_config.keep_checkpoint_every_n_hours)
saver = tf.train.Saver(
sharded=True,
keep_checkpoint_every_n_hours=keep_checkpoint_every_n_hours,
save_relative_paths=True)
tf.add_to_collection(tf.GraphKeys.SAVERS, saver)
scaffold = tf.train.Scaffold(saver=saver)
return tf.estimator.EstimatorSpec(
mode=mode,
predictions=detections,
loss=total_loss,
train_op=train_op,
eval_metric_ops=eval_metric_ops,
export_outputs=export_outputs,
scaffold=scaffold)
return model_fn
def create_estimator_and_inputs(run_config,
hparams,
pipeline_config_path,
config_override=None,
train_steps=None,
sample_1_of_n_eval_examples=None,
sample_1_of_n_eval_on_train_examples=1,
model_fn_creator=create_model_fn,
use_tpu_estimator=False,
use_tpu=False,
num_shards=1,
params=None,
override_eval_num_epochs=True,
save_final_config=False,
postprocess_on_cpu=False,
export_to_tpu=None,
**kwargs):
"""Creates `Estimator`, input functions, and steps.
Args:
run_config: A `RunConfig`.
hparams: A `HParams`.
pipeline_config_path: A path to a pipeline config file.
config_override: A pipeline_pb2.TrainEvalPipelineConfig text proto to
override the config from `pipeline_config_path`.
train_steps: Number of training steps. If None, the number of training steps
is set from the `TrainConfig` proto.
sample_1_of_n_eval_examples: Integer representing how often an eval example
should be sampled. If 1, will sample all examples.
sample_1_of_n_eval_on_train_examples: Similar to
`sample_1_of_n_eval_examples`, except controls the sampling of training
data for evaluation.
model_fn_creator: A function that creates a `model_fn` for `Estimator`.
Follows the signature:
* Args:
* `detection_model_fn`: Function that returns `DetectionModel` instance.
* `configs`: Dictionary of pipeline config objects.
* `hparams`: `HParams` object.
* Returns:
`model_fn` for `Estimator`.
use_tpu_estimator: Whether a `TPUEstimator` should be returned. If False,
an `Estimator` will be returned.
use_tpu: Boolean, whether training and evaluation should run on TPU. Only
used if `use_tpu_estimator` is True.
num_shards: Number of shards (TPU cores). Only used if `use_tpu_estimator`
is True.
params: Parameter dictionary passed from the estimator. Only used if
`use_tpu_estimator` is True.
override_eval_num_epochs: Whether to overwrite the number of epochs to 1 for
eval_input.
save_final_config: Whether to save final config (obtained after applying
overrides) to `estimator.model_dir`.
postprocess_on_cpu: When use_tpu and postprocess_on_cpu are true,
postprocess is scheduled on the host cpu.
export_to_tpu: When use_tpu and export_to_tpu are true,
`export_savedmodel()` exports a metagraph for serving on TPU besides the
one on CPU.
**kwargs: Additional keyword arguments for configuration override.
Returns:
A dictionary with the following fields:
'estimator': An `Estimator` or `TPUEstimator`.
'train_input_fn': A training input function.
'eval_input_fns': A list of all evaluation input functions.
'eval_input_names': A list of names for each evaluation input.
'eval_on_train_input_fn': An evaluation-on-train input function.
'predict_input_fn': A prediction input function.
'train_steps': Number of training steps. Either directly from input or from
configuration.
"""
get_configs_from_pipeline_file = MODEL_BUILD_UTIL_MAP[
'get_configs_from_pipeline_file']
merge_external_params_with_configs = MODEL_BUILD_UTIL_MAP[
'merge_external_params_with_configs']
create_pipeline_proto_from_configs = MODEL_BUILD_UTIL_MAP[
'create_pipeline_proto_from_configs']
create_train_input_fn = MODEL_BUILD_UTIL_MAP['create_train_input_fn']
create_eval_input_fn = MODEL_BUILD_UTIL_MAP['create_eval_input_fn']
create_predict_input_fn = MODEL_BUILD_UTIL_MAP['create_predict_input_fn']
detection_model_fn_base = MODEL_BUILD_UTIL_MAP['detection_model_fn_base']
configs = get_configs_from_pipeline_file(
pipeline_config_path, config_override=config_override)
kwargs.update({
'train_steps': train_steps,
'use_bfloat16': configs['train_config'].use_bfloat16 and use_tpu
})
if sample_1_of_n_eval_examples >= 1:
kwargs.update({
'sample_1_of_n_eval_examples': sample_1_of_n_eval_examples
})
if override_eval_num_epochs:
kwargs.update({'eval_num_epochs': 1})
tf.logging.warning(
'Forced number of epochs for all eval validations to be 1.')
configs = merge_external_params_with_configs(
configs, hparams, kwargs_dict=kwargs)
model_config = configs['model']
train_config = configs['train_config']
train_input_config = configs['train_input_config']
eval_config = configs['eval_config']
eval_input_configs = configs['eval_input_configs']
eval_on_train_input_config = copy.deepcopy(train_input_config)
eval_on_train_input_config.sample_1_of_n_examples = (
sample_1_of_n_eval_on_train_examples)
if override_eval_num_epochs and eval_on_train_input_config.num_epochs != 1:
tf.logging.warning('Expected number of evaluation epochs is 1, but '
'instead encountered `eval_on_train_input_config'
'.num_epochs` = '
'{}. Overwriting `num_epochs` to 1.'.format(
eval_on_train_input_config.num_epochs))
eval_on_train_input_config.num_epochs = 1
# update train_steps from config but only when non-zero value is provided
if train_steps is None and train_config.num_steps != 0:
train_steps = train_config.num_steps
detection_model_fn = functools.partial(
detection_model_fn_base, model_config=model_config)
# Create the input functions for TRAIN/EVAL/PREDICT.
train_input_fn = create_train_input_fn(
train_config=train_config,
train_input_config=train_input_config,
model_config=model_config)
eval_input_fns = [
create_eval_input_fn(
eval_config=eval_config,
eval_input_config=eval_input_config,
model_config=model_config) for eval_input_config in eval_input_configs
]
eval_input_names = [
eval_input_config.name for eval_input_config in eval_input_configs
]
eval_on_train_input_fn = create_eval_input_fn(
eval_config=eval_config,
eval_input_config=eval_on_train_input_config,
model_config=model_config)
predict_input_fn = create_predict_input_fn(
model_config=model_config, predict_input_config=eval_input_configs[0])
# Read export_to_tpu from hparams if not passed.
if export_to_tpu is None:
export_to_tpu = hparams.get('export_to_tpu', False)
tf.logging.info('create_estimator_and_inputs: use_tpu %s, export_to_tpu %s',
use_tpu, export_to_tpu)
model_fn = model_fn_creator(detection_model_fn, configs, hparams, use_tpu,
postprocess_on_cpu)
if use_tpu_estimator:
estimator = tf.contrib.tpu.TPUEstimator(
model_fn=model_fn,
train_batch_size=train_config.batch_size,
# For each core, only batch size 1 is supported for eval.
eval_batch_size=num_shards * 1 if use_tpu else 1,
use_tpu=use_tpu,
config=run_config,
export_to_tpu=export_to_tpu,
eval_on_tpu=False, # Eval runs on CPU, so disable eval on TPU
params=params if params else {})
else:
estimator = tf.estimator.Estimator(model_fn=model_fn, config=run_config)
# Write the as-run pipeline config to disk.
if run_config.is_chief and save_final_config:
pipeline_config_final = create_pipeline_proto_from_configs(configs)
config_util.save_pipeline_config(pipeline_config_final, estimator.model_dir)
return dict(
estimator=estimator,
train_input_fn=train_input_fn,
eval_input_fns=eval_input_fns,
eval_input_names=eval_input_names,
eval_on_train_input_fn=eval_on_train_input_fn,
predict_input_fn=predict_input_fn,
train_steps=train_steps)
def create_train_and_eval_specs(train_input_fn,
eval_input_fns,
eval_on_train_input_fn,
predict_input_fn,
train_steps,
eval_on_train_data=False,
final_exporter_name='Servo',
eval_spec_names=None):
"""Creates a `TrainSpec` and `EvalSpec`s.
Args:
train_input_fn: Function that produces features and labels on train data.
eval_input_fns: A list of functions that produce features and labels on eval
data.
eval_on_train_input_fn: Function that produces features and labels for
evaluation on train data.
predict_input_fn: Function that produces features for inference.
train_steps: Number of training steps.
eval_on_train_data: Whether to evaluate model on training data. Default is
False.
final_exporter_name: String name given to `FinalExporter`.
eval_spec_names: A list of string names for each `EvalSpec`.
Returns:
Tuple of `TrainSpec` and list of `EvalSpecs`. If `eval_on_train_data` is
True, the last `EvalSpec` in the list will correspond to training data. The
rest EvalSpecs in the list are evaluation datas.
"""
train_spec = tf.estimator.TrainSpec(
input_fn=train_input_fn, max_steps=train_steps)
if eval_spec_names is None:
eval_spec_names = [str(i) for i in range(len(eval_input_fns))]
eval_specs = []
for index, (eval_spec_name, eval_input_fn) in enumerate(
zip(eval_spec_names, eval_input_fns)):
# Uses final_exporter_name as exporter_name for the first eval spec for
# backward compatibility.
if index == 0:
exporter_name = final_exporter_name
else:
exporter_name = '{}_{}'.format(final_exporter_name, eval_spec_name)
exporter = tf.estimator.FinalExporter(
name=exporter_name, serving_input_receiver_fn=predict_input_fn)
eval_specs.append(
tf.estimator.EvalSpec(
name=eval_spec_name,
input_fn=eval_input_fn,
steps=None,
exporters=exporter))
if eval_on_train_data:
eval_specs.append(
tf.estimator.EvalSpec(
name='eval_on_train', input_fn=eval_on_train_input_fn, steps=None))
return train_spec, eval_specs
def continuous_eval(estimator, model_dir, input_fn, train_steps, name):
"""Perform continuous evaluation on checkpoints written to a model directory.
Args:
estimator: Estimator object to use for evaluation.
model_dir: Model directory to read checkpoints for continuous evaluation.
input_fn: Input function to use for evaluation.
train_steps: Number of training steps. This is used to infer the last
checkpoint and stop evaluation loop.
name: Namescope for eval summary.
"""
def terminate_eval():
tf.logging.info('Terminating eval after 180 seconds of no checkpoints')
return True
for ckpt in tf.contrib.training.checkpoints_iterator(
model_dir, min_interval_secs=180, timeout=None,
timeout_fn=terminate_eval):
tf.logging.info('Starting Evaluation.')
try:
eval_results = estimator.evaluate(
input_fn=input_fn, steps=None, checkpoint_path=ckpt, name=name)
tf.logging.info('Eval results: %s' % eval_results)
# Terminate eval job when final checkpoint is reached
current_step = int(os.path.basename(ckpt).split('-')[1])
if current_step >= train_steps:
tf.logging.info(
'Evaluation finished after training step %d' % current_step)
break
except tf.errors.NotFoundError:
tf.logging.info(
'Checkpoint %s no longer exists, skipping checkpoint' % ckpt)
def populate_experiment(run_config,
hparams,
pipeline_config_path,
train_steps=None,
eval_steps=None,
model_fn_creator=create_model_fn,
**kwargs):
"""Populates an `Experiment` object.
EXPERIMENT CLASS IS DEPRECATED. Please switch to
tf.estimator.train_and_evaluate. As an example, see model_main.py.
Args:
run_config: A `RunConfig`.
hparams: A `HParams`.
pipeline_config_path: A path to a pipeline config file.
train_steps: Number of training steps. If None, the number of training steps
is set from the `TrainConfig` proto.
eval_steps: Number of evaluation steps per evaluation cycle. If None, the
number of evaluation steps is set from the `EvalConfig` proto.
model_fn_creator: A function that creates a `model_fn` for `Estimator`.
Follows the signature:
* Args:
* `detection_model_fn`: Function that returns `DetectionModel` instance.
* `configs`: Dictionary of pipeline config objects.
* `hparams`: `HParams` object.
* Returns:
`model_fn` for `Estimator`.
**kwargs: Additional keyword arguments for configuration override.
Returns:
An `Experiment` that defines all aspects of training, evaluation, and
export.
"""
tf.logging.warning('Experiment is being deprecated. Please use '
'tf.estimator.train_and_evaluate(). See model_main.py for '
'an example.')
train_and_eval_dict = create_estimator_and_inputs(
run_config,
hparams,
pipeline_config_path,
train_steps=train_steps,
eval_steps=eval_steps,
model_fn_creator=model_fn_creator,
save_final_config=True,
**kwargs)
estimator = train_and_eval_dict['estimator']
train_input_fn = train_and_eval_dict['train_input_fn']
eval_input_fns = train_and_eval_dict['eval_input_fns']
predict_input_fn = train_and_eval_dict['predict_input_fn']
train_steps = train_and_eval_dict['train_steps']
export_strategies = [
tf.contrib.learn.utils.saved_model_export_utils.make_export_strategy(
serving_input_fn=predict_input_fn)
]
return tf.contrib.learn.Experiment(
estimator=estimator,
train_input_fn=train_input_fn,
eval_input_fn=eval_input_fns[0],
train_steps=train_steps,
eval_steps=None,
export_strategies=export_strategies,
eval_delay_secs=120,
)