# 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. # ============================================================================== """object_detection_evaluation module. ObjectDetectionEvaluation is a class which manages ground truth information of a object detection dataset, and computes frequently used detection metrics such as Precision, Recall, CorLoc of the provided detection results. It supports the following operations: 1) Add ground truth information of images sequentially. 2) Add detection result of images sequentially. 3) Evaluate detection metrics on already inserted detection results. 4) Write evaluation result into a pickle file for future processing or visualization. Note: This module operates on numpy boxes and box lists. """ from abc import ABCMeta from abc import abstractmethod import collections import logging import unicodedata import numpy as np import tensorflow as tf from object_detection.core import standard_fields from object_detection.utils import label_map_util from object_detection.utils import metrics from object_detection.utils import per_image_evaluation class DetectionEvaluator(object): """Interface for object detection evalution classes. Example usage of the Evaluator: ------------------------------ evaluator = DetectionEvaluator(categories) # Detections and groundtruth for image 1. evaluator.add_single_groundtruth_image_info(...) evaluator.add_single_detected_image_info(...) # Detections and groundtruth for image 2. evaluator.add_single_groundtruth_image_info(...) evaluator.add_single_detected_image_info(...) metrics_dict = evaluator.evaluate() """ __metaclass__ = ABCMeta def __init__(self, categories): """Constructor. Args: categories: A list of dicts, each of which has the following keys - 'id': (required) an integer id uniquely identifying this category. 'name': (required) string representing category name e.g., 'cat', 'dog'. """ self._categories = categories @abstractmethod def add_single_ground_truth_image_info(self, image_id, groundtruth_dict): """Adds groundtruth for a single image to be used for evaluation. Args: image_id: A unique string/integer identifier for the image. groundtruth_dict: A dictionary of groundtruth numpy arrays required for evaluations. """ pass @abstractmethod def add_single_detected_image_info(self, image_id, detections_dict): """Adds detections for a single image to be used for evaluation. Args: image_id: A unique string/integer identifier for the image. detections_dict: A dictionary of detection numpy arrays required for evaluation. """ pass def get_estimator_eval_metric_ops(self, eval_dict): """Returns dict of metrics to use with `tf.estimator.EstimatorSpec`. Note that this must only be implemented if performing evaluation with a `tf.estimator.Estimator`. Args: eval_dict: A dictionary that holds tensors for evaluating an object detection model, returned from eval_util.result_dict_for_single_example(). Returns: A dictionary of metric names to tuple of value_op and update_op that can be used as eval metric ops in `tf.estimator.EstimatorSpec`. """ pass @abstractmethod def evaluate(self): """Evaluates detections and returns a dictionary of metrics.""" pass @abstractmethod def clear(self): """Clears the state to prepare for a fresh evaluation.""" pass class ObjectDetectionEvaluator(DetectionEvaluator): """A class to evaluate detections.""" def __init__(self, categories, matching_iou_threshold=0.5, evaluate_corlocs=False, evaluate_precision_recall=False, metric_prefix=None, use_weighted_mean_ap=False, evaluate_masks=False, group_of_weight=0.0): """Constructor. Args: categories: A list of dicts, each of which has the following keys - 'id': (required) an integer id uniquely identifying this category. 'name': (required) string representing category name e.g., 'cat', 'dog'. matching_iou_threshold: IOU threshold to use for matching groundtruth boxes to detection boxes. evaluate_corlocs: (optional) boolean which determines if corloc scores are to be returned or not. evaluate_precision_recall: (optional) boolean which determines if precision and recall values are to be returned or not. metric_prefix: (optional) string prefix for metric name; if None, no prefix is used. use_weighted_mean_ap: (optional) boolean which determines if the mean average precision is computed directly from the scores and tp_fp_labels of all classes. evaluate_masks: If False, evaluation will be performed based on boxes. If True, mask evaluation will be performed instead. group_of_weight: Weight of group-of boxes.If set to 0, detections of the correct class within a group-of box are ignored. If weight is > 0, then if at least one detection falls within a group-of box with matching_iou_threshold, weight group_of_weight is added to true positives. Consequently, if no detection falls within a group-of box, weight group_of_weight is added to false negatives. Raises: ValueError: If the category ids are not 1-indexed. """ super(ObjectDetectionEvaluator, self).__init__(categories) self._num_classes = max([cat['id'] for cat in categories]) if min(cat['id'] for cat in categories) < 1: raise ValueError('Classes should be 1-indexed.') self._matching_iou_threshold = matching_iou_threshold self._use_weighted_mean_ap = use_weighted_mean_ap self._label_id_offset = 1 self._evaluate_masks = evaluate_masks self._group_of_weight = group_of_weight self._evaluation = ObjectDetectionEvaluation( num_groundtruth_classes=self._num_classes, matching_iou_threshold=self._matching_iou_threshold, use_weighted_mean_ap=self._use_weighted_mean_ap, label_id_offset=self._label_id_offset, group_of_weight=self._group_of_weight) self._image_ids = set([]) self._evaluate_corlocs = evaluate_corlocs self._evaluate_precision_recall = evaluate_precision_recall self._metric_prefix = (metric_prefix + '_') if metric_prefix else '' self._expected_keys = set([ standard_fields.InputDataFields.key, standard_fields.InputDataFields.groundtruth_boxes, standard_fields.InputDataFields.groundtruth_classes, standard_fields.InputDataFields.groundtruth_difficult, standard_fields.InputDataFields.groundtruth_instance_masks, standard_fields.DetectionResultFields.detection_boxes, standard_fields.DetectionResultFields.detection_scores, standard_fields.DetectionResultFields.detection_classes, standard_fields.DetectionResultFields.detection_masks ]) self._build_metric_names() def _build_metric_names(self): """Builds a list with metric names.""" self._metric_names = [ self._metric_prefix + 'Precision/mAP@{}IOU'.format( self._matching_iou_threshold) ] if self._evaluate_corlocs: self._metric_names.append( self._metric_prefix + 'Precision/meanCorLoc@{}IOU'.format(self._matching_iou_threshold)) category_index = label_map_util.create_category_index(self._categories) for idx in range(self._num_classes): if idx + self._label_id_offset in category_index: category_name = category_index[idx + self._label_id_offset]['name'] try: category_name = unicode(category_name, 'utf-8') except TypeError: pass category_name = unicodedata.normalize('NFKD', category_name).encode( 'ascii', 'ignore') self._metric_names.append( self._metric_prefix + 'PerformanceByCategory/AP@{}IOU/{}'.format( self._matching_iou_threshold, category_name)) if self._evaluate_corlocs: self._metric_names.append( self._metric_prefix + 'PerformanceByCategory/CorLoc@{}IOU/{}' .format(self._matching_iou_threshold, category_name)) def add_single_ground_truth_image_info(self, image_id, groundtruth_dict): """Adds groundtruth for a single image to be used for evaluation. Args: image_id: A unique string/integer identifier for the image. groundtruth_dict: A dictionary containing - standard_fields.InputDataFields.groundtruth_boxes: float32 numpy array of shape [num_boxes, 4] containing `num_boxes` groundtruth boxes of the format [ymin, xmin, ymax, xmax] in absolute image coordinates. standard_fields.InputDataFields.groundtruth_classes: integer numpy array of shape [num_boxes] containing 1-indexed groundtruth classes for the boxes. standard_fields.InputDataFields.groundtruth_difficult: Optional length M numpy boolean array denoting whether a ground truth box is a difficult instance or not. This field is optional to support the case that no boxes are difficult. standard_fields.InputDataFields.groundtruth_instance_masks: Optional numpy array of shape [num_boxes, height, width] with values in {0, 1}. Raises: ValueError: On adding groundtruth for an image more than once. Will also raise error if instance masks are not in groundtruth dictionary. """ if image_id in self._image_ids: raise ValueError('Image with id {} already added.'.format(image_id)) groundtruth_classes = ( groundtruth_dict[standard_fields.InputDataFields.groundtruth_classes] - self._label_id_offset) # If the key is not present in the groundtruth_dict or the array is empty # (unless there are no annotations for the groundtruth on this image) # use values from the dictionary or insert None otherwise. if (standard_fields.InputDataFields.groundtruth_difficult in groundtruth_dict.keys() and (groundtruth_dict[standard_fields.InputDataFields.groundtruth_difficult] .size or not groundtruth_classes.size)): groundtruth_difficult = groundtruth_dict[ standard_fields.InputDataFields.groundtruth_difficult] else: groundtruth_difficult = None if not len(self._image_ids) % 1000: logging.warn( 'image %s does not have groundtruth difficult flag specified', image_id) groundtruth_masks = None if self._evaluate_masks: if (standard_fields.InputDataFields.groundtruth_instance_masks not in groundtruth_dict): raise ValueError('Instance masks not in groundtruth dictionary.') groundtruth_masks = groundtruth_dict[ standard_fields.InputDataFields.groundtruth_instance_masks] self._evaluation.add_single_ground_truth_image_info( image_key=image_id, groundtruth_boxes=groundtruth_dict[ standard_fields.InputDataFields.groundtruth_boxes], groundtruth_class_labels=groundtruth_classes, groundtruth_is_difficult_list=groundtruth_difficult, groundtruth_masks=groundtruth_masks) self._image_ids.update([image_id]) def add_single_detected_image_info(self, image_id, detections_dict): """Adds detections for a single image to be used for evaluation. Args: image_id: A unique string/integer identifier for the image. detections_dict: A dictionary containing - standard_fields.DetectionResultFields.detection_boxes: float32 numpy array of shape [num_boxes, 4] containing `num_boxes` detection boxes of the format [ymin, xmin, ymax, xmax] in absolute image coordinates. standard_fields.DetectionResultFields.detection_scores: float32 numpy array of shape [num_boxes] containing detection scores for the boxes. standard_fields.DetectionResultFields.detection_classes: integer numpy array of shape [num_boxes] containing 1-indexed detection classes for the boxes. standard_fields.DetectionResultFields.detection_masks: uint8 numpy array of shape [num_boxes, height, width] containing `num_boxes` masks of values ranging between 0 and 1. Raises: ValueError: If detection masks are not in detections dictionary. """ detection_classes = ( detections_dict[standard_fields.DetectionResultFields.detection_classes] - self._label_id_offset) detection_masks = None if self._evaluate_masks: if (standard_fields.DetectionResultFields.detection_masks not in detections_dict): raise ValueError('Detection masks not in detections dictionary.') detection_masks = detections_dict[ standard_fields.DetectionResultFields.detection_masks] self._evaluation.add_single_detected_image_info( image_key=image_id, detected_boxes=detections_dict[ standard_fields.DetectionResultFields.detection_boxes], detected_scores=detections_dict[ standard_fields.DetectionResultFields.detection_scores], detected_class_labels=detection_classes, detected_masks=detection_masks) def evaluate(self): """Compute evaluation result. Returns: A dictionary of metrics with the following fields - 1. summary_metrics: '_Precision/mAP@IOU': mean average precision at the specified IOU threshold. 2. per_category_ap: category specific results with keys of the form '_PerformanceByCategory/ mAP@IOU/category'. """ (per_class_ap, mean_ap, per_class_precision, per_class_recall, per_class_corloc, mean_corloc) = ( self._evaluation.evaluate()) pascal_metrics = {self._metric_names[0]: mean_ap} if self._evaluate_corlocs: pascal_metrics[self._metric_names[1]] = mean_corloc category_index = label_map_util.create_category_index(self._categories) for idx in range(per_class_ap.size): if idx + self._label_id_offset in category_index: category_name = category_index[idx + self._label_id_offset]['name'] try: category_name = unicode(category_name, 'utf-8') except TypeError: pass category_name = unicodedata.normalize( 'NFKD', category_name).encode('ascii', 'ignore') display_name = ( self._metric_prefix + 'PerformanceByCategory/AP@{}IOU/{}'.format( self._matching_iou_threshold, category_name)) pascal_metrics[display_name] = per_class_ap[idx] # Optionally add precision and recall values if self._evaluate_precision_recall: display_name = ( self._metric_prefix + 'PerformanceByCategory/Precision@{}IOU/{}'.format( self._matching_iou_threshold, category_name)) pascal_metrics[display_name] = per_class_precision[idx] display_name = ( self._metric_prefix + 'PerformanceByCategory/Recall@{}IOU/{}'.format( self._matching_iou_threshold, category_name)) pascal_metrics[display_name] = per_class_recall[idx] # Optionally add CorLoc metrics.classes if self._evaluate_corlocs: display_name = ( self._metric_prefix + 'PerformanceByCategory/CorLoc@{}IOU/{}' .format(self._matching_iou_threshold, category_name)) pascal_metrics[display_name] = per_class_corloc[idx] return pascal_metrics def clear(self): """Clears the state to prepare for a fresh evaluation.""" self._evaluation = ObjectDetectionEvaluation( num_groundtruth_classes=self._num_classes, matching_iou_threshold=self._matching_iou_threshold, use_weighted_mean_ap=self._use_weighted_mean_ap, label_id_offset=self._label_id_offset) self._image_ids.clear() def get_estimator_eval_metric_ops(self, eval_dict): """Returns dict of metrics to use with `tf.estimator.EstimatorSpec`. Note that this must only be implemented if performing evaluation with a `tf.estimator.Estimator`. Args: eval_dict: A dictionary that holds tensors for evaluating an object detection model, returned from eval_util.result_dict_for_single_example(). It must contain standard_fields.InputDataFields.key. Returns: A dictionary of metric names to tuple of value_op and update_op that can be used as eval metric ops in `tf.estimator.EstimatorSpec`. """ # remove unexpected fields eval_dict_filtered = dict() for key, value in eval_dict.items(): if key in self._expected_keys: eval_dict_filtered[key] = value eval_dict_keys = eval_dict_filtered.keys() def update_op(image_id, *eval_dict_batched_as_list): """Update operation that adds batch of images to ObjectDetectionEvaluator. Args: image_id: image id (single id or an array) *eval_dict_batched_as_list: the values of the dictionary of tensors. """ if np.isscalar(image_id): single_example_dict = dict( zip(eval_dict_keys, eval_dict_batched_as_list)) self.add_single_ground_truth_image_info(image_id, single_example_dict) self.add_single_detected_image_info(image_id, single_example_dict) else: for unzipped_tuple in zip(*eval_dict_batched_as_list): single_example_dict = dict(zip(eval_dict_keys, unzipped_tuple)) image_id = single_example_dict[standard_fields.InputDataFields.key] self.add_single_ground_truth_image_info(image_id, single_example_dict) self.add_single_detected_image_info(image_id, single_example_dict) args = [eval_dict_filtered[standard_fields.InputDataFields.key]] args.extend(eval_dict_filtered.values()) update_op = tf.py_func(update_op, args, []) def first_value_func(): self._metrics = self.evaluate() self.clear() return np.float32(self._metrics[self._metric_names[0]]) def value_func_factory(metric_name): def value_func(): return np.float32(self._metrics[metric_name]) return value_func # Ensure that the metrics are only evaluated once. first_value_op = tf.py_func(first_value_func, [], tf.float32) eval_metric_ops = {self._metric_names[0]: (first_value_op, update_op)} with tf.control_dependencies([first_value_op]): for metric_name in self._metric_names[1:]: eval_metric_ops[metric_name] = (tf.py_func( value_func_factory(metric_name), [], np.float32), update_op) return eval_metric_ops class PascalDetectionEvaluator(ObjectDetectionEvaluator): """A class to evaluate detections using PASCAL metrics.""" def __init__(self, categories, matching_iou_threshold=0.5): super(PascalDetectionEvaluator, self).__init__( categories, matching_iou_threshold=matching_iou_threshold, evaluate_corlocs=False, metric_prefix='PascalBoxes', use_weighted_mean_ap=False) class WeightedPascalDetectionEvaluator(ObjectDetectionEvaluator): """A class to evaluate detections using weighted PASCAL metrics. Weighted PASCAL metrics computes the mean average precision as the average precision given the scores and tp_fp_labels of all classes. In comparison, PASCAL metrics computes the mean average precision as the mean of the per-class average precisions. This definition is very similar to the mean of the per-class average precisions weighted by class frequency. However, they are typically not the same as the average precision is not a linear function of the scores and tp_fp_labels. """ def __init__(self, categories, matching_iou_threshold=0.5): super(WeightedPascalDetectionEvaluator, self).__init__( categories, matching_iou_threshold=matching_iou_threshold, evaluate_corlocs=False, metric_prefix='WeightedPascalBoxes', use_weighted_mean_ap=True) class PascalInstanceSegmentationEvaluator(ObjectDetectionEvaluator): """A class to evaluate instance masks using PASCAL metrics.""" def __init__(self, categories, matching_iou_threshold=0.5): super(PascalInstanceSegmentationEvaluator, self).__init__( categories, matching_iou_threshold=matching_iou_threshold, evaluate_corlocs=False, metric_prefix='PascalMasks', use_weighted_mean_ap=False, evaluate_masks=True) class WeightedPascalInstanceSegmentationEvaluator(ObjectDetectionEvaluator): """A class to evaluate instance masks using weighted PASCAL metrics. Weighted PASCAL metrics computes the mean average precision as the average precision given the scores and tp_fp_labels of all classes. In comparison, PASCAL metrics computes the mean average precision as the mean of the per-class average precisions. This definition is very similar to the mean of the per-class average precisions weighted by class frequency. However, they are typically not the same as the average precision is not a linear function of the scores and tp_fp_labels. """ def __init__(self, categories, matching_iou_threshold=0.5): super(WeightedPascalInstanceSegmentationEvaluator, self).__init__( categories, matching_iou_threshold=matching_iou_threshold, evaluate_corlocs=False, metric_prefix='WeightedPascalMasks', use_weighted_mean_ap=True, evaluate_masks=True) class OpenImagesDetectionEvaluator(ObjectDetectionEvaluator): """A class to evaluate detections using Open Images V2 metrics. Open Images V2 introduce group_of type of bounding boxes and this metric handles those boxes appropriately. """ def __init__(self, categories, matching_iou_threshold=0.5, evaluate_corlocs=False, metric_prefix='OpenImagesV2', group_of_weight=0.0): """Constructor. Args: categories: A list of dicts, each of which has the following keys - 'id': (required) an integer id uniquely identifying this category. 'name': (required) string representing category name e.g., 'cat', 'dog'. matching_iou_threshold: IOU threshold to use for matching groundtruth boxes to detection boxes. evaluate_corlocs: if True, additionally evaluates and returns CorLoc. metric_prefix: Prefix name of the metric. group_of_weight: Weight of the group-of bounding box. If set to 0 (default for Open Images V2 detection protocol), detections of the correct class within a group-of box are ignored. If weight is > 0, then if at least one detection falls within a group-of box with matching_iou_threshold, weight group_of_weight is added to true positives. Consequently, if no detection falls within a group-of box, weight group_of_weight is added to false negatives. """ super(OpenImagesDetectionEvaluator, self).__init__( categories, matching_iou_threshold, evaluate_corlocs, metric_prefix=metric_prefix, group_of_weight=group_of_weight) self._expected_keys = set([ standard_fields.InputDataFields.key, standard_fields.InputDataFields.groundtruth_boxes, standard_fields.InputDataFields.groundtruth_classes, standard_fields.InputDataFields.groundtruth_group_of, standard_fields.DetectionResultFields.detection_boxes, standard_fields.DetectionResultFields.detection_scores, standard_fields.DetectionResultFields.detection_classes, ]) def add_single_ground_truth_image_info(self, image_id, groundtruth_dict): """Adds groundtruth for a single image to be used for evaluation. Args: image_id: A unique string/integer identifier for the image. groundtruth_dict: A dictionary containing - standard_fields.InputDataFields.groundtruth_boxes: float32 numpy array of shape [num_boxes, 4] containing `num_boxes` groundtruth boxes of the format [ymin, xmin, ymax, xmax] in absolute image coordinates. standard_fields.InputDataFields.groundtruth_classes: integer numpy array of shape [num_boxes] containing 1-indexed groundtruth classes for the boxes. standard_fields.InputDataFields.groundtruth_group_of: Optional length M numpy boolean array denoting whether a groundtruth box contains a group of instances. Raises: ValueError: On adding groundtruth for an image more than once. """ if image_id in self._image_ids: raise ValueError('Image with id {} already added.'.format(image_id)) groundtruth_classes = ( groundtruth_dict[standard_fields.InputDataFields.groundtruth_classes] - self._label_id_offset) # If the key is not present in the groundtruth_dict or the array is empty # (unless there are no annotations for the groundtruth on this image) # use values from the dictionary or insert None otherwise. if (standard_fields.InputDataFields.groundtruth_group_of in groundtruth_dict.keys() and (groundtruth_dict[standard_fields.InputDataFields.groundtruth_group_of] .size or not groundtruth_classes.size)): groundtruth_group_of = groundtruth_dict[ standard_fields.InputDataFields.groundtruth_group_of] else: groundtruth_group_of = None if not len(self._image_ids) % 1000: logging.warn( 'image %s does not have groundtruth group_of flag specified', image_id) self._evaluation.add_single_ground_truth_image_info( image_id, groundtruth_dict[standard_fields.InputDataFields.groundtruth_boxes], groundtruth_classes, groundtruth_is_difficult_list=None, groundtruth_is_group_of_list=groundtruth_group_of) self._image_ids.update([image_id]) class OpenImagesDetectionChallengeEvaluator(OpenImagesDetectionEvaluator): """A class implements Open Images Challenge Detection metrics. Open Images Challenge Detection metric has two major changes in comparison with Open Images V2 detection metric: - a custom weight might be specified for detecting an object contained in a group-of box. - verified image-level labels should be explicitelly provided for evaluation: in case in image has neither positive nor negative image level label of class c, all detections of this class on this image will be ignored. """ def __init__(self, categories, matching_iou_threshold=0.5, evaluate_corlocs=False, group_of_weight=1.0): """Constructor. Args: categories: A list of dicts, each of which has the following keys - 'id': (required) an integer id uniquely identifying this category. 'name': (required) string representing category name e.g., 'cat', 'dog'. matching_iou_threshold: IOU threshold to use for matching groundtruth boxes to detection boxes. evaluate_corlocs: if True, additionally evaluates and returns CorLoc. group_of_weight: weight of a group-of box. If set to 0, detections of the correct class within a group-of box are ignored. If weight is > 0 (default for Open Images Detection Challenge 2018), then if at least one detection falls within a group-of box with matching_iou_threshold, weight group_of_weight is added to true positives. Consequently, if no detection falls within a group-of box, weight group_of_weight is added to false negatives. """ super(OpenImagesDetectionChallengeEvaluator, self).__init__( categories, matching_iou_threshold, evaluate_corlocs, metric_prefix='OpenImagesChallenge2018', group_of_weight=group_of_weight) self._evaluatable_labels = {} self._expected_keys = set([ standard_fields.InputDataFields.key, standard_fields.InputDataFields.groundtruth_boxes, standard_fields.InputDataFields.groundtruth_classes, standard_fields.InputDataFields.groundtruth_group_of, standard_fields.InputDataFields.groundtruth_image_classes, standard_fields.DetectionResultFields.detection_boxes, standard_fields.DetectionResultFields.detection_scores, standard_fields.DetectionResultFields.detection_classes, ]) def add_single_ground_truth_image_info(self, image_id, groundtruth_dict): """Adds groundtruth for a single image to be used for evaluation. Args: image_id: A unique string/integer identifier for the image. groundtruth_dict: A dictionary containing - standard_fields.InputDataFields.groundtruth_boxes: float32 numpy array of shape [num_boxes, 4] containing `num_boxes` groundtruth boxes of the format [ymin, xmin, ymax, xmax] in absolute image coordinates. standard_fields.InputDataFields.groundtruth_classes: integer numpy array of shape [num_boxes] containing 1-indexed groundtruth classes for the boxes. standard_fields.InputDataFields.groundtruth_image_classes: integer 1D numpy array containing all classes for which labels are verified. standard_fields.InputDataFields.groundtruth_group_of: Optional length M numpy boolean array denoting whether a groundtruth box contains a group of instances. Raises: ValueError: On adding groundtruth for an image more than once. """ super(OpenImagesDetectionChallengeEvaluator, self).add_single_ground_truth_image_info(image_id, groundtruth_dict) groundtruth_classes = ( groundtruth_dict[standard_fields.InputDataFields.groundtruth_classes] - self._label_id_offset) self._evaluatable_labels[image_id] = np.unique( np.concatenate(((groundtruth_dict.get( standard_fields.InputDataFields.groundtruth_image_classes, np.array([], dtype=int)) - self._label_id_offset), groundtruth_classes))) def add_single_detected_image_info(self, image_id, detections_dict): """Adds detections for a single image to be used for evaluation. Args: image_id: A unique string/integer identifier for the image. detections_dict: A dictionary containing - standard_fields.DetectionResultFields.detection_boxes: float32 numpy array of shape [num_boxes, 4] containing `num_boxes` detection boxes of the format [ymin, xmin, ymax, xmax] in absolute image coordinates. standard_fields.DetectionResultFields.detection_scores: float32 numpy array of shape [num_boxes] containing detection scores for the boxes. standard_fields.DetectionResultFields.detection_classes: integer numpy array of shape [num_boxes] containing 1-indexed detection classes for the boxes. Raises: ValueError: If detection masks are not in detections dictionary. """ if image_id not in self._image_ids: # Since for the correct work of evaluator it is assumed that groundtruth # is inserted first we make sure to break the code if is it not the case. self._image_ids.update([image_id]) self._evaluatable_labels[image_id] = np.array([]) detection_classes = ( detections_dict[standard_fields.DetectionResultFields.detection_classes] - self._label_id_offset) allowed_classes = np.where( np.isin(detection_classes, self._evaluatable_labels[image_id])) detection_classes = detection_classes[allowed_classes] detected_boxes = detections_dict[ standard_fields.DetectionResultFields.detection_boxes][allowed_classes] detected_scores = detections_dict[ standard_fields.DetectionResultFields.detection_scores][allowed_classes] self._evaluation.add_single_detected_image_info( image_key=image_id, detected_boxes=detected_boxes, detected_scores=detected_scores, detected_class_labels=detection_classes) def clear(self): """Clears stored data.""" super(OpenImagesDetectionChallengeEvaluator, self).clear() self._evaluatable_labels.clear() ObjectDetectionEvalMetrics = collections.namedtuple( 'ObjectDetectionEvalMetrics', [ 'average_precisions', 'mean_ap', 'precisions', 'recalls', 'corlocs', 'mean_corloc' ]) class ObjectDetectionEvaluation(object): """Internal implementation of Pascal object detection metrics.""" def __init__(self, num_groundtruth_classes, matching_iou_threshold=0.5, nms_iou_threshold=1.0, nms_max_output_boxes=10000, use_weighted_mean_ap=False, label_id_offset=0, group_of_weight=0.0, per_image_eval_class=per_image_evaluation.PerImageEvaluation): """Constructor. Args: num_groundtruth_classes: Number of ground-truth classes. matching_iou_threshold: IOU threshold used for matching detected boxes to ground-truth boxes. nms_iou_threshold: IOU threshold used for non-maximum suppression. nms_max_output_boxes: Maximum number of boxes returned by non-maximum suppression. use_weighted_mean_ap: (optional) boolean which determines if the mean average precision is computed directly from the scores and tp_fp_labels of all classes. label_id_offset: The label id offset. group_of_weight: Weight of group-of boxes.If set to 0, detections of the correct class within a group-of box are ignored. If weight is > 0, then if at least one detection falls within a group-of box with matching_iou_threshold, weight group_of_weight is added to true positives. Consequently, if no detection falls within a group-of box, weight group_of_weight is added to false negatives. per_image_eval_class: The class that contains functions for computing per image metrics. Raises: ValueError: if num_groundtruth_classes is smaller than 1. """ if num_groundtruth_classes < 1: raise ValueError('Need at least 1 groundtruth class for evaluation.') self.per_image_eval = per_image_eval_class( num_groundtruth_classes=num_groundtruth_classes, matching_iou_threshold=matching_iou_threshold, nms_iou_threshold=nms_iou_threshold, nms_max_output_boxes=nms_max_output_boxes, group_of_weight=group_of_weight) self.group_of_weight = group_of_weight self.num_class = num_groundtruth_classes self.use_weighted_mean_ap = use_weighted_mean_ap self.label_id_offset = label_id_offset self.groundtruth_boxes = {} self.groundtruth_class_labels = {} self.groundtruth_masks = {} self.groundtruth_is_difficult_list = {} self.groundtruth_is_group_of_list = {} self.num_gt_instances_per_class = np.zeros(self.num_class, dtype=float) self.num_gt_imgs_per_class = np.zeros(self.num_class, dtype=int) self._initialize_detections() def _initialize_detections(self): """Initializes internal data structures.""" self.detection_keys = set() self.scores_per_class = [[] for _ in range(self.num_class)] self.tp_fp_labels_per_class = [[] for _ in range(self.num_class)] self.num_images_correctly_detected_per_class = np.zeros(self.num_class) self.average_precision_per_class = np.empty(self.num_class, dtype=float) self.average_precision_per_class.fill(np.nan) self.precisions_per_class = [np.nan] * self.num_class self.recalls_per_class = [np.nan] * self.num_class self.corloc_per_class = np.ones(self.num_class, dtype=float) def clear_detections(self): self._initialize_detections() def add_single_ground_truth_image_info(self, image_key, groundtruth_boxes, groundtruth_class_labels, groundtruth_is_difficult_list=None, groundtruth_is_group_of_list=None, groundtruth_masks=None): """Adds groundtruth for a single image to be used for evaluation. Args: image_key: A unique string/integer identifier for the image. groundtruth_boxes: float32 numpy array of shape [num_boxes, 4] containing `num_boxes` groundtruth boxes of the format [ymin, xmin, ymax, xmax] in absolute image coordinates. groundtruth_class_labels: integer numpy array of shape [num_boxes] containing 0-indexed groundtruth classes for the boxes. groundtruth_is_difficult_list: A length M numpy boolean array denoting whether a ground truth box is a difficult instance or not. To support the case that no boxes are difficult, it is by default set as None. groundtruth_is_group_of_list: A length M numpy boolean array denoting whether a ground truth box is a group-of box or not. To support the case that no boxes are groups-of, it is by default set as None. groundtruth_masks: uint8 numpy array of shape [num_boxes, height, width] containing `num_boxes` groundtruth masks. The mask values range from 0 to 1. """ if image_key in self.groundtruth_boxes: logging.warn( 'image %s has already been added to the ground truth database.', image_key) return self.groundtruth_boxes[image_key] = groundtruth_boxes self.groundtruth_class_labels[image_key] = groundtruth_class_labels self.groundtruth_masks[image_key] = groundtruth_masks if groundtruth_is_difficult_list is None: num_boxes = groundtruth_boxes.shape[0] groundtruth_is_difficult_list = np.zeros(num_boxes, dtype=bool) self.groundtruth_is_difficult_list[ image_key] = groundtruth_is_difficult_list.astype(dtype=bool) if groundtruth_is_group_of_list is None: num_boxes = groundtruth_boxes.shape[0] groundtruth_is_group_of_list = np.zeros(num_boxes, dtype=bool) self.groundtruth_is_group_of_list[ image_key] = groundtruth_is_group_of_list.astype(dtype=bool) self._update_ground_truth_statistics( groundtruth_class_labels, groundtruth_is_difficult_list.astype(dtype=bool), groundtruth_is_group_of_list.astype(dtype=bool)) def add_single_detected_image_info(self, image_key, detected_boxes, detected_scores, detected_class_labels, detected_masks=None): """Adds detections for a single image to be used for evaluation. Args: image_key: A unique string/integer identifier for the image. detected_boxes: float32 numpy array of shape [num_boxes, 4] containing `num_boxes` detection boxes of the format [ymin, xmin, ymax, xmax] in absolute image coordinates. detected_scores: float32 numpy array of shape [num_boxes] containing detection scores for the boxes. detected_class_labels: integer numpy array of shape [num_boxes] containing 0-indexed detection classes for the boxes. detected_masks: np.uint8 numpy array of shape [num_boxes, height, width] containing `num_boxes` detection masks with values ranging between 0 and 1. Raises: ValueError: if the number of boxes, scores and class labels differ in length. """ if (len(detected_boxes) != len(detected_scores) or len(detected_boxes) != len(detected_class_labels)): raise ValueError('detected_boxes, detected_scores and ' 'detected_class_labels should all have same lengths. Got' '[%d, %d, %d]' % len(detected_boxes), len(detected_scores), len(detected_class_labels)) if image_key in self.detection_keys: logging.warn( 'image %s has already been added to the detection result database', image_key) return self.detection_keys.add(image_key) if image_key in self.groundtruth_boxes: groundtruth_boxes = self.groundtruth_boxes[image_key] groundtruth_class_labels = self.groundtruth_class_labels[image_key] # Masks are popped instead of look up. The reason is that we do not want # to keep all masks in memory which can cause memory overflow. groundtruth_masks = self.groundtruth_masks.pop( image_key) groundtruth_is_difficult_list = self.groundtruth_is_difficult_list[ image_key] groundtruth_is_group_of_list = self.groundtruth_is_group_of_list[ image_key] else: groundtruth_boxes = np.empty(shape=[0, 4], dtype=float) groundtruth_class_labels = np.array([], dtype=int) if detected_masks is None: groundtruth_masks = None else: groundtruth_masks = np.empty(shape=[0, 1, 1], dtype=float) groundtruth_is_difficult_list = np.array([], dtype=bool) groundtruth_is_group_of_list = np.array([], dtype=bool) scores, tp_fp_labels, is_class_correctly_detected_in_image = ( self.per_image_eval.compute_object_detection_metrics( detected_boxes=detected_boxes, detected_scores=detected_scores, detected_class_labels=detected_class_labels, groundtruth_boxes=groundtruth_boxes, groundtruth_class_labels=groundtruth_class_labels, groundtruth_is_difficult_list=groundtruth_is_difficult_list, groundtruth_is_group_of_list=groundtruth_is_group_of_list, detected_masks=detected_masks, groundtruth_masks=groundtruth_masks)) for i in range(self.num_class): if scores[i].shape[0] > 0: self.scores_per_class[i].append(scores[i]) self.tp_fp_labels_per_class[i].append(tp_fp_labels[i]) (self.num_images_correctly_detected_per_class ) += is_class_correctly_detected_in_image def _update_ground_truth_statistics(self, groundtruth_class_labels, groundtruth_is_difficult_list, groundtruth_is_group_of_list): """Update grouth truth statitistics. 1. Difficult boxes are ignored when counting the number of ground truth instances as done in Pascal VOC devkit. 2. Difficult boxes are treated as normal boxes when computing CorLoc related statitistics. Args: groundtruth_class_labels: An integer numpy array of length M, representing M class labels of object instances in ground truth groundtruth_is_difficult_list: A boolean numpy array of length M denoting whether a ground truth box is a difficult instance or not groundtruth_is_group_of_list: A boolean numpy array of length M denoting whether a ground truth box is a group-of box or not """ for class_index in range(self.num_class): num_gt_instances = np.sum(groundtruth_class_labels[ ~groundtruth_is_difficult_list & ~groundtruth_is_group_of_list] == class_index) num_groupof_gt_instances = self.group_of_weight * np.sum( groundtruth_class_labels[groundtruth_is_group_of_list] == class_index) self.num_gt_instances_per_class[ class_index] += num_gt_instances + num_groupof_gt_instances if np.any(groundtruth_class_labels == class_index): self.num_gt_imgs_per_class[class_index] += 1 def evaluate(self): """Compute evaluation result. Returns: A named tuple with the following fields - average_precision: float numpy array of average precision for each class. mean_ap: mean average precision of all classes, float scalar precisions: List of precisions, each precision is a float numpy array recalls: List of recalls, each recall is a float numpy array corloc: numpy float array mean_corloc: Mean CorLoc score for each class, float scalar """ if (self.num_gt_instances_per_class == 0).any(): logging.warn( 'The following classes have no ground truth examples: %s', np.squeeze(np.argwhere(self.num_gt_instances_per_class == 0)) + self.label_id_offset) if self.use_weighted_mean_ap: all_scores = np.array([], dtype=float) all_tp_fp_labels = np.array([], dtype=bool) for class_index in range(self.num_class): if self.num_gt_instances_per_class[class_index] == 0: continue if not self.scores_per_class[class_index]: scores = np.array([], dtype=float) tp_fp_labels = np.array([], dtype=float) else: scores = np.concatenate(self.scores_per_class[class_index]) tp_fp_labels = np.concatenate(self.tp_fp_labels_per_class[class_index]) if self.use_weighted_mean_ap: all_scores = np.append(all_scores, scores) all_tp_fp_labels = np.append(all_tp_fp_labels, tp_fp_labels) precision, recall = metrics.compute_precision_recall( scores, tp_fp_labels, self.num_gt_instances_per_class[class_index]) self.precisions_per_class[class_index] = precision self.recalls_per_class[class_index] = recall average_precision = metrics.compute_average_precision(precision, recall) self.average_precision_per_class[class_index] = average_precision logging.info('average_precision: %f', average_precision) self.corloc_per_class = metrics.compute_cor_loc( self.num_gt_imgs_per_class, self.num_images_correctly_detected_per_class) if self.use_weighted_mean_ap: num_gt_instances = np.sum(self.num_gt_instances_per_class) precision, recall = metrics.compute_precision_recall( all_scores, all_tp_fp_labels, num_gt_instances) mean_ap = metrics.compute_average_precision(precision, recall) else: mean_ap = np.nanmean(self.average_precision_per_class) mean_corloc = np.nanmean(self.corloc_per_class) return ObjectDetectionEvalMetrics( self.average_precision_per_class, mean_ap, self.precisions_per_class, self.recalls_per_class, self.corloc_per_class, mean_corloc)