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object_detection_metrics.py
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object_detection_metrics.py
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# Copyright 2019 Google LLC
#
# 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
#
# https://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.
"""COCO object detection metrics."""
import logging
import math
from typing import Any, Dict, List, Optional, Tuple, Union
import numpy as np
from tensorflow_model_analysis.metrics import confusion_matrix_metrics
from tensorflow_model_analysis.metrics import metric_types
from tensorflow_model_analysis.metrics import metric_util
from tensorflow_model_analysis.metrics import object_detection_confusion_matrix_metrics
AVERAGE_RECALL_NAME = 'average_recall'
AVERAGE_PRECISION_NAME = 'average_precision'
MEAN_AVERAGE_PRECISION_NAME = 'mean_average_precision'
MEAN_AVERAGE_RECALL_NAME = 'mean_average_recall'
class COCOAveragePrecision(metric_types.Metric):
"""Confusion matrix at thresholds.
It computes the average precision of object detections for a single class and
a single iou_threshold.
"""
def __init__(self,
num_thresholds: Optional[int] = None,
iou_threshold: Optional[float] = None,
class_id: Optional[int] = None,
class_weight: Optional[float] = None,
area_range: Optional[Tuple[float, float]] = None,
max_num_detections: Optional[int] = None,
recalls: Optional[List[float]] = None,
num_recalls: Optional[int] = None,
name: Optional[str] = None,
labels_to_stack: Optional[List[str]] = None,
predictions_to_stack: Optional[List[str]] = None,
num_detections_key: Optional[str] = None,
allow_missing_key: bool = False):
"""Initialize average precision metric.
This metric is only used in object-detection setting. It does not support
sub_key parameters due to the matching algorithm of bounding boxes.
The metric supports using multiple outputs to form the labels/predictions if
the user specifies the label/predcition keys to stack. In this case, the
metric is not expected to work with multi-outputs. The metric only supports
multi outputs if the output of model is already pre-stacked in the expected
format, i.e. ['xmin', 'ymin', 'xmax', 'ymax', 'class_id'] for labels and
['xmin', 'ymin', 'xmax', 'ymax', 'class_id', 'confidence scores'] for
predictions.
Args:
num_thresholds: (Optional) Number of thresholds to use for calculating the
matrices and finding the precision at given recall.
iou_threshold: (Optional) Threholds for a detection and ground truth pair
with specific iou to be considered as a match.
class_id: (Optional) The class id for calculating metrics.
class_weight: (Optional) The weight associated with the object class id.
area_range: (Optional) The area-range for objects to be considered for
metrics.
max_num_detections: (Optional) The maximum number of detections for a
single image.
recalls: (Optional) recalls at which precisions will be calculated.
num_recalls: (Optional) Used for objecth detection, the number of recalls
for calculating average precision, it equally generates points bewteen 0
and 1. (Only one of recalls and num_recalls should be used).
name: (Optional) string name of the metric instance.
labels_to_stack: (Optional) Keys for columns to be stacked as a single
numpy array as the labels. It is searched under the key labels, features
and transformed features. The desired format is [left bounadary, top
boudnary, right boundary, bottom boundary, class id]. e.g. ['xmin',
'ymin', 'xmax', 'ymax', 'class_id']
predictions_to_stack: (Optional) Output names for columns to be stacked as
a single numpy array as the prediction. It should be the model's output
names. The desired format is [left bounadary, top boudnary, right
boundary, bottom boundary, class id, confidence score]. e.g. ['xmin',
'ymin', 'xmax', 'ymax', 'class_id', 'scores']
num_detections_key: (Optional) An output name in which to find the number
of detections to use for evaluation for a given example. It does nothing
if predictions_to_stack is not set. The value for this output should be
a scalar value or a single-value tensor. The stacked predicitions will
be truncated with the specified number of detections.
allow_missing_key: (Optional) If true, the preprocessor will return empty
array instead of raising errors.
"""
if recalls is not None:
recall_thresholds = recalls
elif num_recalls is not None:
recall_thresholds = np.linspace(0.0, 1.0, num_recalls)
else:
# by default set recall_thresholds to [0.0:0.01:1.0].
recall_thresholds = np.linspace(0.0, 1.0, 101)
super().__init__(
metric_util.merge_per_key_computations(self._metric_computations),
num_thresholds=num_thresholds,
iou_threshold=iou_threshold,
class_id=class_id,
class_weight=class_weight,
area_range=area_range,
max_num_detections=max_num_detections,
recall_thresholds=recall_thresholds,
name=name,
labels_to_stack=labels_to_stack,
predictions_to_stack=predictions_to_stack,
num_detections_key=num_detections_key,
allow_missing_key=allow_missing_key)
def _default_name(self) -> str:
return AVERAGE_PRECISION_NAME
def _metric_computations(
self,
num_thresholds: Optional[int] = None,
iou_threshold: Optional[float] = None,
class_id: Optional[int] = None,
class_weight: Optional[float] = None,
max_num_detections: Optional[int] = None,
area_range: Optional[Tuple[float, float]] = None,
recall_thresholds: Optional[List[float]] = None,
name: Optional[str] = None,
model_name: str = '',
output_name: str = '',
example_weighted: bool = False,
labels_to_stack: Optional[List[str]] = None,
predictions_to_stack: Optional[List[str]] = None,
num_detections_key: Optional[str] = None,
allow_missing_key: bool = False,
) -> metric_types.MetricComputations:
"""Returns computations for confusion matrix metric."""
metric_util.validate_object_detection_arguments(
class_id=class_id,
class_weight=class_weight,
area_range=area_range,
max_num_detections=max_num_detections,
labels_to_stack=labels_to_stack,
predictions_to_stack=predictions_to_stack,
output_name=output_name)
key = metric_types.MetricKey(
name=name,
model_name=model_name,
output_name=output_name,
sub_key=None,
example_weighted=example_weighted,
aggregation_type=None)
if recall_thresholds is None:
# If recall thresholds is not defined, initialize it as [0.0]
recall_thresholds = [0.0]
if num_thresholds is None:
num_thresholds = 10000
thresholds = [1.e-12] + [
(i + 1) * 1.0 / (num_thresholds - 1) for i in range(num_thresholds - 2)
] + [1.0 - 1.e-12]
# PrecisionAtRecall is a public function. To hide it from users who do not
# need it, we make the name private with '_'.
precision_at_recall_name = metric_util.generate_private_name_from_arguments(
confusion_matrix_metrics.PRECISION_AT_RECALL_NAME,
recall=recall_thresholds,
num_thresholds=num_thresholds,
iou_threshold=iou_threshold,
class_id=class_id,
class_weight=class_weight,
area_range=area_range,
max_num_detections=max_num_detections,
allow_missing_key=allow_missing_key)
pr = (
object_detection_confusion_matrix_metrics
.ObjectDetectionPrecisionAtRecall(
recall=recall_thresholds,
thresholds=thresholds,
iou_threshold=iou_threshold,
class_id=class_id,
class_weight=class_weight,
area_range=area_range,
max_num_detections=max_num_detections,
name=precision_at_recall_name,
labels_to_stack=labels_to_stack,
predictions_to_stack=predictions_to_stack,
num_detections_key=num_detections_key,
allow_missing_key=allow_missing_key))
computations = pr.computations(
model_names=[model_name], output_names=[output_name])
precisions_key = computations[-1].keys[-1]
def result(
metrics: Dict[metric_types.MetricKey, Any]
) -> Dict[metric_types.MetricKey, Union[float, np.ndarray]]:
value = np.nanmean(metrics[precisions_key])
return {key: value}
derived_computation = metric_types.DerivedMetricComputation(
keys=[key], result=result)
computations.append(derived_computation)
return computations
metric_types.register_metric(COCOAveragePrecision)
class COCOMeanAveragePrecision(metric_types.Metric):
"""Mean average precision for object detections.
It calculates the mean average precision metric for object detections. It
averages COCOAveragePrecision over multiple classes and IoU thresholds.
"""
def __init__(self,
num_thresholds: Optional[int] = None,
iou_thresholds: Optional[List[float]] = None,
class_ids: Optional[List[int]] = None,
class_weights: Optional[List[float]] = None,
area_range: Optional[Tuple[float, float]] = None,
max_num_detections: Optional[int] = None,
recalls: Optional[List[float]] = None,
num_recalls: Optional[int] = None,
name: Optional[str] = None,
labels_to_stack: Optional[List[str]] = None,
predictions_to_stack: Optional[List[str]] = None,
num_detections_key: Optional[str] = None,
allow_missing_key: bool = False):
"""Initializes mean average precision metric.
This metric is only used in object-detection setting. It does not support
sub_key parameters due to the matching algorithm of bounding boxes.
The metric supports using multiple outputs to form the labels/predictions if
the user specifies the label/predcition keys to stack. In this case, the
metric is not expected to work with multi-outputs. The metric only supports
multi outputs if the output of model is already pre-stacked in the expected
format, i.e. ['xmin', 'ymin', 'xmax', 'ymax', 'class_id'] for labels and
['xmin', 'ymin', 'xmax', 'ymax', 'class_id', 'confidence scores'] for
predictions.
Args:
num_thresholds: (Optional) Number of thresholds to use for calculating the
matrices and finding the precision at given recall.
iou_thresholds: (Optional) Threholds for a detection and ground truth pair
with specific iou to be considered as a match.
class_ids: (Optional) The class ids for calculating metrics.
class_weights: (Optional) The weight associated with the object class ids.
If it is provided, it should have the same length as class_ids.
area_range: (Optional) The area-range for objects to be considered for
metrics.
max_num_detections: (Optional) The maximum number of detections for a
single image.
recalls: (Optional) recalls at which precisions will be calculated.
num_recalls: (Optional) Used for objecth detection, the number of recalls
for calculating average precision, it equally generates points bewteen 0
and 1. (Only one of recalls and num_recalls should be used).
name: (Optional) Metric name.
labels_to_stack: (Optional) Keys for columns to be stacked as a single
numpy array as the labels. It is searched under the key labels, features
and transformed features. The desired format is [left bounadary, top
boudnary, right boundary, bottom boundary, class id]. e.g. ['xmin',
'ymin', 'xmax', 'ymax', 'class_id']
predictions_to_stack: (Optional) Output names for columns to be stacked as
a single numpy array as the prediction. It should be the model's output
names. The desired format is [left bounadary, top boudnary, right
boundary, bottom boundary, class id, confidence score]. e.g. ['xmin',
'ymin', 'xmax', 'ymax', 'class_id', 'scores']
num_detections_key: (Optional) An output name in which to find the number
of detections to use for evaluation for a given example. It does nothing
if predictions_to_stack is not set. The value for this output should be
a scalar value or a single-value tensor. The stacked predicitions will
be truncated with the specified number of detections.
allow_missing_key: (Optional) If true, the preprocessor will return empty
array instead of raising errors.
"""
super().__init__(
metric_util.merge_per_key_computations(self._metric_computations),
num_thresholds=num_thresholds,
iou_thresholds=iou_thresholds,
class_ids=class_ids,
class_weights=class_weights,
area_range=area_range,
max_num_detections=max_num_detections,
recalls=recalls,
num_recalls=num_recalls,
name=name,
labels_to_stack=labels_to_stack,
predictions_to_stack=predictions_to_stack,
num_detections_key=num_detections_key,
allow_missing_key=allow_missing_key)
def _default_name(self) -> str:
return MEAN_AVERAGE_PRECISION_NAME
def _metric_computations(self,
num_thresholds: Optional[int] = None,
iou_thresholds: Optional[List[float]] = None,
class_ids: Optional[List[int]] = None,
class_weights: Optional[List[float]] = None,
max_num_detections: Optional[int] = None,
area_range: Optional[Tuple[float, float]] = None,
recalls: Optional[List[float]] = None,
num_recalls: Optional[int] = None,
name: Optional[str] = None,
model_name: str = '',
output_name: str = '',
example_weighted: bool = False,
labels_to_stack: Optional[List[str]] = None,
predictions_to_stack: Optional[List[str]] = None,
num_detections_key: Optional[str] = None,
allow_missing_key: bool = False,
**kwargs) -> metric_types.MetricComputations:
"""Returns computations for confusion matrix metric."""
metric_util.validate_object_detection_arguments(
class_id=class_ids,
class_weight=class_weights,
area_range=area_range,
max_num_detections=max_num_detections,
labels_to_stack=labels_to_stack,
predictions_to_stack=predictions_to_stack,
output_name=output_name)
# set default value according to COCO metrics
if iou_thresholds is None:
iou_thresholds = np.linspace(0.5, 0.95, 10)
if class_weights is None:
class_weights = [1.0] * len(class_ids)
key = metric_types.MetricKey(
name=name,
model_name=model_name,
output_name=output_name,
sub_key=None,
example_weighted=example_weighted,
aggregation_type=None)
computations = []
precisions_keys = []
for iou_threshold in iou_thresholds:
for class_id, class_weight in zip(class_ids, class_weights):
average_precision_name = (
metric_util.generate_private_name_from_arguments(
AVERAGE_PRECISION_NAME,
recall=recalls,
num_recalls=num_recalls,
num_thresholds=num_thresholds,
iou_threshold=iou_threshold,
class_id=class_id,
class_weight=class_weight,
area_range=area_range,
max_num_detections=max_num_detections,
allow_missing_key=allow_missing_key))
ap = COCOAveragePrecision(
num_thresholds=num_thresholds,
iou_threshold=iou_threshold,
class_id=class_id,
class_weight=class_weight,
area_range=area_range,
max_num_detections=max_num_detections,
recalls=recalls,
num_recalls=num_recalls,
name=average_precision_name,
labels_to_stack=labels_to_stack,
predictions_to_stack=predictions_to_stack,
num_detections_key=num_detections_key,
allow_missing_key=allow_missing_key)
computations.extend(
ap.computations(
model_names=[model_name], output_names=[output_name]))
precisions_keys.append(computations[-1].keys[-1])
def result(
metrics: Dict[metric_types.MetricKey, Any]
) -> Dict[metric_types.MetricKey, Union[float, np.ndarray]]:
precisions = [
metrics[precisions_key] for precisions_key in precisions_keys
]
value = np.nanmean(precisions)
return {key: value}
derived_computation = metric_types.DerivedMetricComputation(
keys=[key], result=result)
computations.append(derived_computation)
return computations
metric_types.register_metric(COCOMeanAveragePrecision)
class COCOAverageRecall(metric_types.Metric):
"""Average recall metric for object detection.
It computes the average precision metric for object detections for a single
class. It averages MaxRecall metric over mulitple IoU thresholds.
"""
def __init__(self,
iou_thresholds: Optional[List[float]] = None,
class_id: Optional[int] = None,
class_weight: Optional[float] = None,
area_range: Optional[Tuple[float, float]] = None,
max_num_detections: Optional[int] = None,
name: Optional[str] = None,
labels_to_stack: Optional[List[str]] = None,
predictions_to_stack: Optional[List[str]] = None,
num_detections_key: Optional[str] = None,
allow_missing_key: bool = False):
"""Initializes average recall metric.
This metric is only used in object-detection setting. It does not support
sub_key parameters due to the matching algorithm of bounding boxes.
The metric supports using multiple outputs to form the labels/predictions if
the user specifies the label/predcition keys to stack. In this case, the
metric is not expected to work with multi-outputs. The metric only supports
multi outputs if the output of model is already pre-stacked in the expected
format, i.e. ['xmin', 'ymin', 'xmax', 'ymax', 'class_id'] for labels and
['xmin', 'ymin', 'xmax', 'ymax', 'class_id', 'confidence scores'] for
predictions.
Args:
iou_thresholds: (Optional) Threholds for a detection and ground truth pair
with specific iou to be considered as a match.
class_id: (Optional) The class ids for calculating metrics.
class_weight: (Optional) The weight associated with the object class ids.
If it is provided, it should have the same length as class_ids.
area_range: (Optional) The area-range for objects to be considered for
metrics.
max_num_detections: (Optional) The maximum number of detections for a
single image.
name: (Optional) Metric name.
labels_to_stack: (Optional) Keys for columns to be stacked as a single
numpy array as the labels. It is searched under the key labels, features
and transformed features. The desired format is [left bounadary, top
boudnary, right boundary, bottom boundary, class id]. e.g. ['xmin',
'ymin', 'xmax', 'ymax', 'class_id']
predictions_to_stack: (Optional) Output names for columns to be stacked as
a single numpy array as the prediction. It should be the model's output
names. The desired format is [left bounadary, top boudnary, right
boundary, bottom boundary, class id, confidence score]. e.g. ['xmin',
'ymin', 'xmax', 'ymax', 'class_id', 'scores']
num_detections_key: (Optional) An output name in which to find the number
of detections to use for evaluation for a given example. It does nothing
if predictions_to_stack is not set. The value for this output should be
a scalar value or a single-value tensor. The stacked predicitions will
be truncated with the specified number of detections.
allow_missing_key: (Optional) If true, the preprocessor will return empty
array instead of raising errors.
"""
super().__init__(
metric_util.merge_per_key_computations(self._metric_computations),
iou_thresholds=iou_thresholds,
class_id=class_id,
class_weight=class_weight,
area_range=area_range,
max_num_detections=max_num_detections,
name=name,
labels_to_stack=labels_to_stack,
predictions_to_stack=predictions_to_stack,
num_detections_key=num_detections_key,
allow_missing_key=allow_missing_key)
def _default_name(self) -> str:
return AVERAGE_RECALL_NAME
def _metric_computations(
self,
iou_thresholds: Optional[Union[float, List[float]]] = None,
class_id: Optional[int] = None,
class_weight: Optional[float] = None,
max_num_detections: Optional[int] = None,
area_range: Optional[Tuple[float, float]] = None,
name: Optional[str] = None,
model_name: str = '',
output_name: str = '',
example_weighted: bool = False,
labels_to_stack: Optional[List[str]] = None,
predictions_to_stack: Optional[List[str]] = None,
num_detections_key: Optional[str] = None,
allow_missing_key: bool = False,
) -> metric_types.MetricComputations:
"""Returns computations for confusion matrix metric."""
metric_util.validate_object_detection_arguments(
class_id=class_id,
class_weight=class_weight,
area_range=area_range,
max_num_detections=max_num_detections,
labels_to_stack=labels_to_stack,
predictions_to_stack=predictions_to_stack,
output_name=output_name)
# set default value according to COCO metrics
if iou_thresholds is None:
iou_thresholds = np.linspace(0.5, 0.95, 10)
if class_weight is None:
class_weight = 1.0
key = metric_types.MetricKey(
name=name,
model_name=model_name,
output_name=output_name,
sub_key=None,
example_weighted=example_weighted,
aggregation_type=None)
computations = []
recalls_keys = []
for iou_threshold in iou_thresholds:
max_recall_name = metric_util.generate_private_name_from_arguments(
confusion_matrix_metrics.MAX_RECALL_NAME,
iou_threshold=iou_threshold,
class_id=class_id,
class_weight=class_weight,
area_range=area_range,
max_num_detections=max_num_detections,
allow_missing_key=allow_missing_key)
mr = object_detection_confusion_matrix_metrics.ObjectDetectionMaxRecall(
iou_threshold=iou_threshold,
class_id=class_id,
class_weight=class_weight,
area_range=area_range,
max_num_detections=max_num_detections,
name=max_recall_name,
labels_to_stack=labels_to_stack,
predictions_to_stack=predictions_to_stack,
num_detections_key=num_detections_key,
allow_missing_key=allow_missing_key)
computations.extend(
mr.computations(model_names=[model_name], output_names=[output_name]))
recalls_keys.append(computations[-1].keys[-1])
def result(
metrics: Dict[metric_types.MetricKey, Any]
) -> Dict[metric_types.MetricKey, Union[float, np.ndarray]]:
for recalls_key in recalls_keys:
if math.isnan(metrics[recalls_key]):
logging.warning(
'Recall with metric key %s is NaN, it will be'
' ignored in the following calculation.', recalls_key)
recalls = [metrics[recalls_key] for recalls_key in recalls_keys]
value = np.nanmean(recalls)
return {key: value}
derived_computation = metric_types.DerivedMetricComputation(
keys=[key], result=result)
computations.append(derived_computation)
return computations
metric_types.register_metric(COCOAverageRecall)
class COCOMeanAverageRecall(metric_types.Metric):
"""Mean Average recall metric for object detection.
It computes the mean average precision metric for object detections for a
single class. It averages COCOAverageRecall metric over mulitple classes.
"""
def __init__(self,
iou_thresholds: Optional[List[float]] = None,
class_ids: Optional[List[int]] = None,
class_weights: Optional[List[float]] = None,
area_range: Optional[Tuple[float, float]] = None,
max_num_detections: Optional[int] = None,
name: Optional[str] = None,
labels_to_stack: Optional[List[str]] = None,
predictions_to_stack: Optional[List[str]] = None,
num_detections_key: Optional[str] = None,
allow_missing_key: bool = False):
"""Initializes average recall metric.
This metric is only used in object-detection setting. It does not support
sub_key parameters due to the matching algorithm of bounding boxes.
The metric supports using multiple outputs to form the labels/predictions if
the user specifies the label/predcition keys to stack. In this case, the
metric is not expected to work with multi-outputs. The metric only supports
multi outputs if the output of model is already pre-stacked in the expected
format, i.e. ['xmin', 'ymin', 'xmax', 'ymax', 'class_id'] for labels and
['xmin', 'ymin', 'xmax', 'ymax', 'class_id', 'confidence scores'] for
predictions.
Args:
iou_thresholds: (Optional) Threholds for a detection and ground truth pair
with specific iou to be considered as a match.
class_ids: (Optional) The class ids for calculating metrics.
class_weights: (Optional) The weight associated with the object class ids.
If it is provided, it should have the same length as class_ids.
area_range: (Optional) The area-range for objects to be considered for
metrics.
max_num_detections: (Optional) The maximum number of detections for a
single image.
name: (Optional) Metric name.
labels_to_stack: (Optional) Keys for columns to be stacked as a single
numpy array as the labels. It is searched under the key labels, features
and transformed features. The desired format is [left bounadary, top
boudnary, right boundary, bottom boundary, class id]. e.g. ['xmin',
'ymin', 'xmax', 'ymax', 'class_id']
predictions_to_stack: (Optional) Output names for columns to be stacked as
a single numpy array as the prediction. It should be the model's output
names. The desired format is [left bounadary, top boudnary, right
boundary, bottom boundary, class id, confidence score]. e.g. ['xmin',
'ymin', 'xmax', 'ymax', 'class_id', 'scores']
num_detections_key: (Optional) An output name in which to find the number
of detections to use for evaluation for a given example. It does nothing
if predictions_to_stack is not set. The value for this output should be
a scalar value or a single-value tensor. The stacked predicitions will
be truncated with the specified number of detections.
allow_missing_key: (Optional) If true, the preprocessor will return empty
array instead of raising errors.
"""
super().__init__(
metric_util.merge_per_key_computations(self._metric_computations),
iou_thresholds=iou_thresholds,
class_ids=class_ids,
class_weights=class_weights,
area_range=area_range,
max_num_detections=max_num_detections,
name=name,
labels_to_stack=labels_to_stack,
predictions_to_stack=predictions_to_stack,
num_detections_key=num_detections_key,
allow_missing_key=allow_missing_key)
def _default_name(self) -> str:
return MEAN_AVERAGE_RECALL_NAME
def _metric_computations(
self,
iou_thresholds: Optional[List[float]] = None,
class_ids: Optional[Union[int, List[int]]] = None,
class_weights: Optional[Union[float, List[float]]] = None,
max_num_detections: Optional[int] = None,
area_range: Optional[Tuple[float, float]] = None,
name: Optional[str] = None,
model_name: str = '',
output_name: str = '',
example_weighted: bool = False,
labels_to_stack: Optional[List[str]] = None,
predictions_to_stack: Optional[List[str]] = None,
num_detections_key: Optional[str] = None,
allow_missing_key: bool = False,
) -> metric_types.MetricComputations:
"""Returns computations for confusion matrix metric."""
metric_util.validate_object_detection_arguments(
class_id=class_ids,
class_weight=class_weights,
area_range=area_range,
max_num_detections=max_num_detections,
labels_to_stack=labels_to_stack,
predictions_to_stack=predictions_to_stack,
output_name=output_name)
if class_weights is None:
class_weights = [1.0] * len(class_ids)
key = metric_types.MetricKey(
name=name,
model_name=model_name,
output_name=output_name,
sub_key=None,
example_weighted=example_weighted,
aggregation_type=None)
computations = []
recalls_keys = []
for class_id, class_weight in zip(class_ids, class_weights):
max_recall_name = metric_util.generate_private_name_from_arguments(
AVERAGE_RECALL_NAME,
iou_thresholds=iou_thresholds,
class_id=class_id,
class_weight=class_weight,
area_range=area_range,
max_num_detections=max_num_detections,
allow_missing_key=allow_missing_key)
mr = COCOAverageRecall(
iou_thresholds=iou_thresholds,
class_id=class_id,
class_weight=class_weight,
area_range=area_range,
max_num_detections=max_num_detections,
name=max_recall_name,
labels_to_stack=labels_to_stack,
predictions_to_stack=predictions_to_stack,
num_detections_key=num_detections_key,
allow_missing_key=allow_missing_key)
computations.extend(
mr.computations(model_names=[model_name], output_names=[output_name]))
recalls_keys.append(computations[-1].keys[-1])
def result(
metrics: Dict[metric_types.MetricKey, Any]
) -> Dict[metric_types.MetricKey, Union[float, np.ndarray]]:
recalls = [metrics[recalls_key] for recalls_key in recalls_keys]
value = np.nanmean(recalls)
return {key: value}
derived_computation = metric_types.DerivedMetricComputation(
keys=[key], result=result)
computations.append(derived_computation)
return computations
metric_types.register_metric(COCOMeanAverageRecall)