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) # Set policy for mixed-precision training with Keras-based models. if use_tpu and train_config.use_bfloat16: from tensorflow.python.keras.engine import base_layer_utils # pylint: disable=g-import-not-at-top # Enable v2 behavior, as `mixed_bfloat16` is only supported in TF 2.0. base_layer_utils.enable_v2_dtype_behavior() tf2.keras.mixed_precision.experimental.set_policy('mixed_bfloat16') 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] side_inputs = detection_model.get_side_inputs(features) if use_tpu and train_config.use_bfloat16: with tf.tpu.bfloat16_scope(): prediction_dict = detection_model.predict( preprocessed_images, features[fields.InputDataFields.true_image_shape], **side_inputs) prediction_dict = ops.bfloat16_to_float32_nested( prediction_dict) else: prediction_dict = detection_model.predict( preprocessed_images, features[fields.InputDataFields.true_image_shape], **side_inputs) 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.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: load_pretrained = hparams.load_pretrained if hparams else False if train_config.fine_tune_checkpoint and 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): if (mode == tf.estimator.ModeKeys.EVAL and eval_config.use_dummy_loss_in_eval): total_loss = tf.constant(1.0) losses_dict = {'Loss/total_loss': total_loss} else: 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.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 = slim.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 = slim.optimizers.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 fields.InputDataFields.image_additional_channels in features: eval_dict[fields.InputDataFields. image_additional_channels] = features[ fields.InputDataFields.image_additional_channels] 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: keypoint_edges = [(kp.start, kp.end) for kp in eval_config.keypoint_edge] 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, keypoint_edges=keypoint_edges or None) 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.estimator.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)
def test_eval_metric_ops(self): if self.is_tf2(): self.skipTest( 'This test is only compatible with Tensorflow 1.X, ' 'estimator eval ops are not supported in Tensorflow 2.') category_index = { 1: { 'id': 1, 'name': 'dog' }, 2: { 'id': 2, 'name': 'cat' } } max_examples_to_draw = 4 metric_op_base = 'Detections_Left_Groundtruth_Right' eval_metric_ops = visualization_utils.VisualizeSingleFrameDetections( category_index, max_examples_to_draw=max_examples_to_draw, summary_name_prefix=metric_op_base) original_image = tf.placeholder(tf.uint8, [4, None, None, 3]) original_image_spatial_shape = tf.placeholder(tf.int32, [4, 2]) true_image_shape = tf.placeholder(tf.int32, [4, 3]) detection_boxes = tf.random_uniform([4, 20, 4], minval=0.0, maxval=1.0, dtype=tf.float32) detection_classes = tf.random_uniform([4, 20], minval=1, maxval=3, dtype=tf.int64) detection_scores = tf.random_uniform([4, 20], minval=0., maxval=1., dtype=tf.float32) groundtruth_boxes = tf.random_uniform([4, 8, 4], minval=0.0, maxval=1.0, dtype=tf.float32) num_groundtruth_boxes = tf.constant([3, 8, 0, 2], tf.int32) groundtruth_classes = tf.random_uniform([4, 8], minval=1, maxval=3, dtype=tf.int64) eval_dict = { fields.DetectionResultFields.detection_boxes: detection_boxes, fields.DetectionResultFields.detection_classes: detection_classes, fields.DetectionResultFields.detection_scores: detection_scores, fields.InputDataFields.original_image: original_image, fields.InputDataFields.original_image_spatial_shape: (original_image_spatial_shape), fields.InputDataFields.true_image_shape: (true_image_shape), fields.InputDataFields.groundtruth_boxes: groundtruth_boxes, fields.InputDataFields.groundtruth_classes: groundtruth_classes, fields.InputDataFields.num_groundtruth_boxes: num_groundtruth_boxes } metric_ops = eval_metric_ops.get_estimator_eval_metric_ops(eval_dict) _, update_op = metric_ops[next(six.iterkeys(metric_ops))] with self.test_session() as sess: sess.run(tf.global_variables_initializer()) value_ops = {} for key, (value_op, _) in six.iteritems(metric_ops): value_ops[key] = value_op # First run enough update steps to surpass `max_examples_to_draw`. for i in range(max_examples_to_draw): # Use a unique image shape on each eval image. sess.run(update_op, feed_dict={ original_image: np.random.randint(low=0, high=256, size=(4, 6 + i, 7 + i, 3), dtype=np.uint8), original_image_spatial_shape: [[6 + i, 7 + i], [6 + i, 7 + i], [6 + i, 7 + i], [6 + i, 7 + i]], true_image_shape: [[6 + i, 7 + i, 3], [6 + i, 7 + i, 3], [6 + i, 7 + i, 3], [6 + i, 7 + i, 3]] }) value_ops_out = sess.run(value_ops) for key, value_op in six.iteritems(value_ops_out): self.assertNotEqual('', value_op) # Now run fewer update steps than `max_examples_to_draw`. A single value # op will be the empty string, since not enough image summaries can be # produced. for i in range(max_examples_to_draw - 1): # Use a unique image shape on each eval image. sess.run(update_op, feed_dict={ original_image: np.random.randint(low=0, high=256, size=(4, 6 + i, 7 + i, 3), dtype=np.uint8), original_image_spatial_shape: [[6 + i, 7 + i], [6 + i, 7 + i], [6 + i, 7 + i], [6 + i, 7 + i]], true_image_shape: [[6 + i, 7 + i, 3], [6 + i, 7 + i, 3], [6 + i, 7 + i, 3], [6 + i, 7 + i, 3]] }) value_ops_out = sess.run(value_ops) self.assertEqual( six.b(''), value_ops_out[metric_op_base + '/' + str(max_examples_to_draw - 1)])
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 = True if boxes_shape[ 1] is not None else False labels = unstack_batch( labels, unpad_groundtruth_tensors=unpad_groundtruth_tensors) if mode in (tf.estimator.ModeKeys.TRAIN, tf.estimator.ModeKeys.EVAL): 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_is_crowd_list = None if fields.InputDataFields.groundtruth_is_crowd in labels: gt_is_crowd_list = labels[ fields.InputDataFields.groundtruth_is_crowd] detection_model.provide_groundtruth( groundtruth_boxes_list=gt_boxes_list, groundtruth_classes_list=gt_classes_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) 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]) for k, v in prediction_dict.items(): if v.dtype == tf.bfloat16: prediction_dict[k] = tf.cast(v, tf.float32) else: prediction_dict = detection_model.predict( preprocessed_images, features[fields.InputDataFields.true_image_shape]) if mode in (tf.estimator.ModeKeys.EVAL, tf.estimator.ModeKeys.PREDICT): detections = detection_model.postprocess( 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 = tf.get_collection( tf.GraphKeys.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 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, variables=trainable_variables, summaries=summaries, name='') # Preventing scope prefix on all variables. if mode == tf.estimator.ModeKeys.PREDICT: export_outputs = { tf.saved_model.signature_constants.PREDICT_METHOD_NAME: tf.estimator.export.PredictOutput(detections) } 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) use_original_images = fields.InputDataFields.original_image in features if use_original_images: eval_images = tf.cast( tf.image.resize_bilinear( features[fields.InputDataFields.original_image][0:1], features[fields.InputDataFields. original_image_spatial_shape][0]), tf.uint8) else: eval_images = features[fields.InputDataFields.image] eval_dict = eval_util.result_dict_for_single_example( eval_images[0:1], features[inputs.HASH_KEY][0], detections, groundtruth, class_agnostic=class_agnostic, scale_to_absolute=True) 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, 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: 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)
def test_eval_metric_ops(self): category_index = {1: {'id': 1, 'name': 'dog'}, 2: {'id': 2, 'name': 'cat'}} max_examples_to_draw = 4 metric_op_base = 'Detections_Left_Groundtruth_Right' eval_metric_ops = visualization_utils.VisualizeSingleFrameDetections( category_index, max_examples_to_draw=max_examples_to_draw, summary_name_prefix=metric_op_base) original_image = tf.placeholder(tf.uint8, [1, None, None, 3]) detection_boxes = tf.random_uniform([20, 4], minval=0.0, maxval=1.0, dtype=tf.float32) detection_classes = tf.random_uniform([20], minval=1, maxval=3, dtype=tf.int64) detection_scores = tf.random_uniform([20], minval=0., maxval=1., dtype=tf.float32) groundtruth_boxes = tf.random_uniform([8, 4], minval=0.0, maxval=1.0, dtype=tf.float32) groundtruth_classes = tf.random_uniform([8], minval=1, maxval=3, dtype=tf.int64) eval_dict = { fields.DetectionResultFields.detection_boxes: detection_boxes, fields.DetectionResultFields.detection_classes: detection_classes, fields.DetectionResultFields.detection_scores: detection_scores, fields.InputDataFields.original_image: original_image, fields.InputDataFields.groundtruth_boxes: groundtruth_boxes, fields.InputDataFields.groundtruth_classes: groundtruth_classes} metric_ops = eval_metric_ops.get_estimator_eval_metric_ops(eval_dict) _, update_op = metric_ops[metric_ops.keys()[0]] with self.test_session() as sess: sess.run(tf.global_variables_initializer()) value_ops = {} for key, (value_op, _) in metric_ops.iteritems(): value_ops[key] = value_op # First run enough update steps to surpass `max_examples_to_draw`. for i in range(max_examples_to_draw): # Use a unique image shape on each eval image. sess.run(update_op, feed_dict={ original_image: np.random.randint(low=0, high=256, size=(1, 6 + i, 7 + i, 3), dtype=np.uint8) }) value_ops_out = sess.run(value_ops) for key, value_op in value_ops_out.iteritems(): self.assertNotEqual('', value_op) # Now run fewer update steps than `max_examples_to_draw`. A single value # op will be the empty string, since not enough image summaries can be # produced. for i in range(max_examples_to_draw - 1): # Use a unique image shape on each eval image. sess.run(update_op, feed_dict={ original_image: np.random.randint(low=0, high=256, size=(1, 6 + i, 7 + i, 3), dtype=np.uint8) }) value_ops_out = sess.run(value_ops) self.assertEqual( '', value_ops_out[metric_op_base + '/' + str(max_examples_to_draw - 1)])
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 scaffold = None eval_metric_ops = None if mode == tf.estimator.ModeKeys.TRAIN: # get the optimizer and global step: global_step = tf.train.get_or_create_global_step() training_optimizer, optimizer_summary_vars = optimizer_builder.build( train_config.optimizer) #get the trainable variables #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) #get the clip_gradients_value clip_gradients_value = None if train_config.gradient_clipping_by_norm > 0: clip_gradients_value = train_config.gradient_clipping_by_norm total_loss = 0. tower_grads = [] with tf.variable_scope(tf.get_variable_scope()): feature_list, label_list = split_features_and_labels( features, labels, train_config.GPU_num) for i in xrange(train_config.GPU_num): with tf.device('/gpu:%d' % i): with tf.name_scope('%s_%d' % ('tower', i)) as scope: loss = tower_loss(scope=scope, features=feature_list[i], labels=label_list[i], detection_model=detection_model, train_config=train_config) tf.get_variable_scope().reuse_variables() grads = training_optimizer.compute_gradients( loss=loss) if isinstance(clip_gradients_value, float): grads = clip_gradients_by_norm( grads, clip_gradients_value) tower_grads.append(grads) total_loss += loss total_loss /= train_config.GPU_num grad_avg = average_gradients(tower_grads) with tf.control_dependencies( tf.get_collection(tf.GraphKeys.UPDATE_OPS)): apply_gradient_op = training_optimizer.apply_gradients( grads_and_vars=grad_avg, global_step=global_step) train_op = apply_gradient_op if train_config.fine_tune_checkpoint: 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) elif mode == tf.estimator.ModeKeys.EVAL: detection_model = detection_model_fn(is_training=is_training, add_summaries=(not use_tpu)) # For evaling on train data, it is necessary to check whether groundtruth # must be unpadded. #in mode == tf.estimator.ModeKeys.EVAL or mode == tf.estimator.ModeKeys.PREDICT, I explictly set the evaluation and prediction to run on CPU with tf.device('/cpu:1'): # training_optimizer, optimizer_summary_vars = optimizer_builder.build( train_config.optimizer ) 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) 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] detection_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) training_optimizer, optimizer_summary_vars = optimizer_builder.build( train_config.optimizer) 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]) for k, v in prediction_dict.items(): if v.dtype == tf.bfloat16: prediction_dict[k] = tf.cast(v, tf.float32) else: prediction_dict = detection_model.predict( preprocessed_images, features[fields.InputDataFields.true_image_shape]) detections = detection_model.postprocess( prediction_dict, features[fields.InputDataFields.true_image_shape]) 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 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() 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, 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) elif mode == tf.estimator.ModeKeys.PREDICT: detection_model = detection_model_fn(is_training=is_training, add_summaries=(not use_tpu)) #similar to EVAL mode, I run PREDICT on CPU too. with tf.device(':/cpu:1'): 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]) for k, v in prediction_dict.items(): if v.dtype == tf.bfloat16: prediction_dict[k] = tf.cast(v, tf.float32) else: prediction_dict = detection_model.predict( preprocessed_images, features[fields.InputDataFields.true_image_shape]) detections = detection_model.postprocess( prediction_dict, features[fields.InputDataFields.true_image_shape]) 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 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: #scafold here only contains Saver 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)