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BBoxMaskPose-demo / mmpose /evaluation /metrics /coco_metric.py
Miroslav Purkrabek
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 # Copyright (c) OpenMMLab. All rights reserved.
import datetime
import os.path as osp
import tempfile
from collections import OrderedDict, defaultdict
from typing import Dict, Optional, Sequence
import traceback
import numpy as np
from mmengine.evaluator import BaseMetric
from mmengine.fileio import dump, get_local_path, load
from mmengine.logging import MessageHub, MMLogger, print_log
from xtcocotools.coco import COCO
from xtcocotools.cocoeval import COCOeval
from mmpose.registry import METRICS
from mmpose.structures.bbox import bbox_xyxy2xywh
from mmpose.structures.keypoint import find_min_padding_exact, fix_bbox_aspect_ratio
from ..functional import (oks_nms, soft_oks_nms, transform_ann, transform_pred,
transform_sigmas)
import cv2
import os
import matplotlib.pyplot as plt
from matplotlib import rc
from xtcocotools.mask import _mask as maskUtils
@METRICS.register_module()
class CocoMetric(BaseMetric):
"""COCO pose estimation task evaluation metric.
Evaluate AR, AP, and mAP for keypoint detection tasks. Support COCO
dataset and other datasets in COCO format. Please refer to
`COCO keypoint evaluation <https://cocodataset.org/#keypoints-eval>`__
for more details.
Args:
ann_file (str, optional): Path to the coco format annotation file.
If not specified, ground truth annotations from the dataset will
be converted to coco format. Defaults to None
use_area (bool): Whether to use ``'area'`` message in the annotations.
If the ground truth annotations (e.g. CrowdPose, AIC) do not have
the field ``'area'``, please set ``use_area=False``.
Defaults to ``True``
iou_type (str): The same parameter as `iouType` in
:class:`xtcocotools.COCOeval`, which can be ``'keypoints'``, or
``'keypoints_crowd'`` (used in CrowdPose dataset).
Defaults to ``'keypoints'``
score_mode (str): The mode to score the prediction results which
should be one of the following options:
- ``'bbox'``: Take the score of bbox as the score of the
prediction results.
- ``'bbox_keypoint'``: Use keypoint score to rescore the
prediction results.
- ``'bbox_rle'``: Use rle_score to rescore the
prediction results.
Defaults to ``'bbox_keypoint'`
keypoint_score_thr (float): The threshold of keypoint score. The
keypoints with score lower than it will not be included to
rescore the prediction results. Valid only when ``score_mode`` is
``bbox_keypoint``. Defaults to ``0.2``
nms_mode (str): The mode to perform Non-Maximum Suppression (NMS),
which should be one of the following options:
- ``'oks_nms'``: Use Object Keypoint Similarity (OKS) to
perform NMS.
- ``'soft_oks_nms'``: Use Object Keypoint Similarity (OKS)
to perform soft NMS.
- ``'none'``: Do not perform NMS. Typically for bottomup mode
output.
Defaults to ``'oks_nms'`
nms_thr (float): The Object Keypoint Similarity (OKS) threshold
used in NMS when ``nms_mode`` is ``'oks_nms'`` or
``'soft_oks_nms'``. Will retain the prediction results with OKS
lower than ``nms_thr``. Defaults to ``0.9``
format_only (bool): Whether only format the output results without
doing quantitative evaluation. This is designed for the need of
test submission when the ground truth annotations are absent. If
set to ``True``, ``outfile_prefix`` should specify the path to
store the output results. Defaults to ``False``
pred_converter (dict, optional): Config dictionary for the prediction
converter. The dictionary has the same parameters as
'KeypointConverter'. Defaults to None.
gt_converter (dict, optional): Config dictionary for the ground truth
converter. The dictionary has the same parameters as
'KeypointConverter'. Defaults to None.
outfile_prefix (str | None): The prefix of json files. It includes
the file path and the prefix of filename, e.g., ``'a/b/prefix'``.
If not specified, a temp file will be created. Defaults to ``None``
collect_device (str): Device name used for collecting results from
different ranks during distributed training. Must be ``'cpu'`` or
``'gpu'``. Defaults to ``'cpu'``
prefix (str, optional): The prefix that will be added in the metric
names to disambiguate homonymous metrics of different evaluators.
If prefix is not provided in the argument, ``self.default_prefix``
will be used instead. Defaults to ``None``
"""
default_prefix: Optional[str] = 'coco'
def __init__(self,
ann_file: Optional[str] = None,
use_area: bool = True,
iou_type: str = 'keypoints',
score_mode: str = 'bbox_keypoint',
score_thresh_type: str = 'score',
keypoint_score_thr: float = 0.2,
nms_mode: str = 'oks_nms',
nms_thr: float = 0.9,
format_only: bool = False,
pred_converter: Dict = None,
gt_converter: Dict = None,
outfile_prefix: Optional[str] = None,
collect_device: str = 'cpu',
prefix: Optional[str] = None,
extended: list = [False],
match_by_bbox: list = [False],
ignore_border_points: list = [False],
ignore_stats: list = [],
padding: float = 1.25) -> None:
super().__init__(collect_device=collect_device, prefix=prefix)
self.ann_file = ann_file
# initialize coco helper with the annotation json file
# if ann_file is not specified, initialize with the converted dataset
if ann_file is not None:
with get_local_path(ann_file) as local_path:
self.coco = COCO(local_path)
else:
self.coco = None
self.use_area = use_area
self.iou_type = iou_type
allowed_score_modes = ['bbox', 'bbox_keypoint', 'bbox_rle', 'keypoint']
if score_mode not in allowed_score_modes:
raise ValueError(
"`score_mode` should be one of 'bbox', 'bbox_keypoint', "
f"'bbox_rle', but got {score_mode}")
self.score_mode = score_mode
self.keypoint_score_thr = keypoint_score_thr
if score_thresh_type not in ['score', 'prob']:
raise ValueError(
"'score_thresh_type' should be one of 'score' or 'prob'"
)
self.score_thresh_type = score_thresh_type
allowed_nms_modes = ['oks_nms', 'soft_oks_nms', 'none']
if nms_mode not in allowed_nms_modes:
raise ValueError(
"`nms_mode` should be one of 'oks_nms', 'soft_oks_nms', "
f"'none', but got {nms_mode}")
self.nms_mode = nms_mode
self.nms_thr = nms_thr
if format_only:
assert outfile_prefix is not None, '`outfile_prefix` can not be '\
'None when `format_only` is True, otherwise the result file '\
'will be saved to a temp directory which will be cleaned up '\
'in the end.'
elif ann_file is not None:
# do evaluation only if the ground truth annotations exist
assert 'annotations' in load(ann_file), \
'Ground truth annotations are required for evaluation '\
'when `format_only` is False.'
self.format_only = format_only
self.outfile_prefix = outfile_prefix
self.pred_converter = pred_converter
self.gt_converter = gt_converter
len_params = max(len(extended), len(match_by_bbox))
if len(extended) == 1 and len_params > 1:
extended = extended * len_params
if len(match_by_bbox) == 1 and len_params > 1:
match_by_bbox = match_by_bbox * len_params
assert len(extended) == len(match_by_bbox), \
'The length of `extended` and `match_by_bbox` should be the same.'
assert len(extended) >= 1, \
'The length of `extended` and `match_by_bbox` should be at least 1.'
self.extended = extended
self.match_by_bbox = match_by_bbox
self.ignore_border_points = ignore_border_points
self.ignore_stats = ignore_stats
self.prob_thr = -1
self.has_probability = True
self.padding = padding
self._compute_min_padding_in_coco()
@property
def dataset_meta(self) -> Optional[dict]:
"""Optional[dict]: Meta info of the dataset."""
return self._dataset_meta
@dataset_meta.setter
def dataset_meta(self, dataset_meta: dict) -> None:
"""Set the dataset meta info to the metric."""
if self.gt_converter is not None:
dataset_meta['sigmas'] = transform_sigmas(
dataset_meta['sigmas'], self.gt_converter['num_keypoints'],
self.gt_converter['mapping'])
dataset_meta['num_keypoints'] = len(dataset_meta['sigmas'])
self._dataset_meta = dataset_meta
if self.coco is None:
message = MessageHub.get_current_instance()
ann_file = message.get_info(
f"{dataset_meta['dataset_name']}_ann_file", None)
if ann_file is not None:
with get_local_path(ann_file) as local_path:
self.coco = COCO(local_path)
print_log(
f'CocoMetric for dataset '
f"{dataset_meta['dataset_name']} has successfully "
f'loaded the annotation file from {ann_file}', 'current')
def _compute_min_padding_in_coco(self):
"""Compute the minimum padding in COCO format."""
if self.coco is None:
return
for _, ann in self.coco.anns.items():
if 'pad_to_contain' in ann.keys():
continue
kpts = np.array(ann['keypoints']).reshape(-1, 3)
bbox = np.array(ann['bbox']).flatten()
min_padding = find_min_padding_exact(bbox, kpts)
ann['pad_to_contain'] = min_padding
return
def process(self, data_batch: Sequence[dict],
data_samples: Sequence[dict]) -> None:
"""Process one batch of data samples and predictions. The processed
results should be stored in ``self.results``, which will be used to
compute the metrics when all batches have been processed.
Args:
data_batch (Sequence[dict]): A batch of data
from the dataloader.
data_samples (Sequence[dict]): A batch of outputs from
the model, each of which has the following keys:
- 'id': The id of the sample
- 'img_id': The image_id of the sample
- 'pred_instances': The prediction results of instance(s)
"""
self.results_len = len(self.results)
for data_sample in data_samples:
if 'pred_instances' not in data_sample:
raise ValueError(
'`pred_instances` are required to process the '
f'predictions results in {self.__class__.__name__}. ')
# keypoints.shape: [N, K, 2],
# N: number of instances, K: number of keypoints
# for topdown-style output, N is usually 1, while for
# bottomup-style output, N is the number of instances in the image
keypoints = data_sample['pred_instances']['keypoints']
N, K, _ = keypoints.shape
# [N, K], the scores for all keypoints of all instances
keypoint_scores = data_sample['pred_instances']['keypoint_scores']
assert keypoint_scores.shape == keypoints.shape[:2]
if 'keypoints_visible' in data_sample['pred_instances']:
keypoints_visible = data_sample['pred_instances']['keypoints_visible']
else:
keypoints_visible = keypoint_scores.copy()
if 'keypoints_probs' in data_sample['pred_instances']:
keypoints_probs = data_sample['pred_instances']['keypoints_probs']
# keypoints_probs = keypoint_scores.copy()
else:
self.has_probability = False
keypoints_probs = keypoint_scores.copy()
if 'keypoints_oks' in data_sample['pred_instances']:
keypoints_oks = data_sample['pred_instances']['keypoints_oks']
else:
keypoints_oks = keypoint_scores.copy()
if 'keypoints_error' in data_sample['pred_instances']:
keypoints_error = data_sample['pred_instances']['keypoints_error']
else:
keypoints_error = keypoint_scores.copy()
if K == 21:
# Translate 21 keypoints to 17 keypoints by ignoring the last 4 keypoints
keypoints = keypoints[:, :17, :]
keypoint_scores = keypoint_scores[:, :17]
keypoints_visible = keypoints_visible[:, :17]
keypoints_probs = keypoints_probs[:, :17]
keypoints_oks = keypoints_oks[:, :17]
keypoints_error = keypoints_error[:, :17]
elif K != 17:
raise ValueError('The number of keypoints should be 17 or 21, '
f'but got {K}.')
assert keypoints.shape[1] == 17, f'Number of keypoints should be 17 but got {keypoints.shape}'
assert keypoint_scores.shape[1] == 17, f'Number of keypoint scores should be 17 but got {keypoint_scores.shape}'
assert keypoints_visible.shape[1] == 17, f'Number of visible keypoints should be 17 but got {keypoints_visible.shape}'
assert keypoints_probs.shape[1] == 17, f'Number of keypoint probs should be 17 but got {keypoints_probs.shape}'
assert keypoints_oks.shape[1] == 17, f'Number of keypoint oks should be 17 but got {keypoints_oks.shape}'
assert keypoints_error.shape[1] == 17, f'Number of keypoint error should be 17 but got {keypoints_error.shape}'
assert heatmaps.shape[1] == 17, f'Number of heatmaps should be 17 but got {heatmaps.shape}'
# parse prediction results
pred = dict()
pred['id'] = data_sample['id']
pred['img_id'] = data_sample['img_id']
pred['keypoints'] = keypoints
pred['keypoint_scores'] = keypoint_scores
pred['keypoints_visible'] = keypoints_visible
pred['keypoint_probs'] = keypoints_probs
pred['keypoint_oks'] = keypoints_oks
pred['keypoint_error'] = keypoints_error
pred['category_id'] = data_sample.get('category_id', 1)
if 'bboxes' in data_sample['pred_instances']:
pred['bbox'] = bbox_xyxy2xywh(
data_sample['pred_instances']['bboxes'])
if 'bbox_scores' in data_sample['pred_instances']:
# some one-stage models will predict bboxes and scores
# together with keypoints
bbox_scores = data_sample['pred_instances']['bbox_scores']
elif ('bbox_scores' not in data_sample['gt_instances']
or len(data_sample['gt_instances']['bbox_scores']) !=
len(keypoints)):
# bottom-up models might output different number of
# instances from annotation
bbox_scores = np.ones(len(keypoints))
else:
# top-down models use detected bboxes, the scores of which
# are contained in the gt_instances
bbox_scores = data_sample['gt_instances']['bbox_scores']
pred['bbox_scores'] = bbox_scores
# get area information
if 'bbox_scales' in data_sample['gt_instances']:
pred['areas'] = np.prod(
data_sample['gt_instances']['bbox_scales'], axis=1)
# parse gt
gt = dict()
if self.coco is None:
gt['width'] = data_sample['ori_shape'][1]
gt['height'] = data_sample['ori_shape'][0]
gt['img_id'] = data_sample['img_id']
if self.iou_type == 'keypoints_crowd':
assert 'crowd_index' in data_sample, \
'`crowd_index` is required when `self.iou_type` is ' \
'`keypoints_crowd`'
gt['crowd_index'] = data_sample['crowd_index']
assert 'raw_ann_info' in data_sample, \
'The row ground truth annotations are required for ' \
'evaluation when `ann_file` is not provided'
anns = data_sample['raw_ann_info']
gt['raw_ann_info'] = anns if isinstance(anns, list) else [anns]
# add converted result to the results list
self.results.append((pred, gt))
processed_len = len(self.results) - self.results_len
if processed_len != len(data_samples):
print(f'Warning: {processed_len} samples are processed, ')
print(f'but {len(data_samples)} samples are provided.')
def gt_to_coco_json(self, gt_dicts: Sequence[dict],
outfile_prefix: str) -> str:
"""Convert ground truth to coco format json file.
Args:
gt_dicts (Sequence[dict]): Ground truth of the dataset. Each dict
contains the ground truth information about the data sample.
Required keys of the each `gt_dict` in `gt_dicts`:
- `img_id`: image id of the data sample
- `width`: original image width
- `height`: original image height
- `raw_ann_info`: the raw annotation information
Optional keys:
- `crowd_index`: measure the crowding level of an image,
defined in CrowdPose dataset
It is worth mentioning that, in order to compute `CocoMetric`,
there are some required keys in the `raw_ann_info`:
- `id`: the id to distinguish different annotations
- `image_id`: the image id of this annotation
- `category_id`: the category of the instance.
- `bbox`: the object bounding box
- `keypoints`: the keypoints cooridinates along with their
visibilities. Note that it need to be aligned
with the official COCO format, e.g., a list with length
N * 3, in which N is the number of keypoints. And each
triplet represent the [x, y, visible] of the keypoint.
- `iscrowd`: indicating whether the annotation is a crowd.
It is useful when matching the detection results to
the ground truth.
There are some optional keys as well:
- `area`: it is necessary when `self.use_area` is `True`
- `num_keypoints`: it is necessary when `self.iou_type`
is set as `keypoints_crowd`.
outfile_prefix (str): The filename prefix of the json files. If the
prefix is "somepath/xxx", the json file will be named
"somepath/xxx.gt.json".
Returns:
str: The filename of the json file.
"""
image_infos = []
annotations = []
img_ids = []
ann_ids = []
for gt_dict in gt_dicts:
# filter duplicate image_info
if gt_dict['img_id'] not in img_ids:
image_info = dict(
id=gt_dict['img_id'],
width=gt_dict['width'],
height=gt_dict['height'],
)
if self.iou_type == 'keypoints_crowd':
image_info['crowdIndex'] = gt_dict['crowd_index']
image_infos.append(image_info)
img_ids.append(gt_dict['img_id'])
# filter duplicate annotations
for ann in gt_dict['raw_ann_info']:
if ann is None:
# during evaluation on bottom-up datasets, some images
# do not have instance annotation
continue
annotation = dict(
id=ann['id'],
image_id=ann['image_id'],
category_id=ann['category_id'],
bbox=ann['bbox'],
keypoints=ann['keypoints'],
iscrowd=ann['iscrowd'],
)
if self.use_area:
assert 'area' in ann, \
'`area` is required when `self.use_area` is `True`'
annotation['area'] = ann['area']
if self.iou_type == 'keypoints_crowd':
assert 'num_keypoints' in ann, \
'`num_keypoints` is required when `self.iou_type` ' \
'is `keypoints_crowd`'
annotation['num_keypoints'] = ann['num_keypoints']
annotations.append(annotation)
ann_ids.append(ann['id'])
info = dict(
date_created=str(datetime.datetime.now()),
description='Coco json file converted by mmpose CocoMetric.')
coco_json = dict(
info=info,
images=image_infos,
categories=self.dataset_meta['CLASSES'],
licenses=None,
annotations=annotations,
)
converted_json_path = f'{outfile_prefix}.gt.json'
dump(coco_json, converted_json_path, sort_keys=True, indent=4)
return converted_json_path
def compute_metrics(self, results: list) -> Dict[str, float]:
"""Compute the metrics from processed results.
Args:
results (list): The processed results of each batch.
Returns:
Dict[str, float]: The computed metrics. The keys are the names of
the metrics, and the values are corresponding results.
"""
logger: MMLogger = MMLogger.get_current_instance()
# split prediction and gt list
preds, gts = zip(*results)
tmp_dir = None
if self.outfile_prefix is None:
tmp_dir = tempfile.TemporaryDirectory()
outfile_prefix = osp.join(tmp_dir.name, 'results')
else:
outfile_prefix = self.outfile_prefix
if self.coco is None:
# use converted gt json file to initialize coco helper
logger.info('Converting ground truth to coco format...')
coco_json_path = self.gt_to_coco_json(
gt_dicts=gts, outfile_prefix=outfile_prefix)
self.coco = COCO(coco_json_path)
if self.gt_converter is not None:
for id_, ann in self.coco.anns.items():
self.coco.anns[id_] = transform_ann(
ann, self.gt_converter['num_keypoints'],
self.gt_converter['mapping'])
kpts = defaultdict(list)
# group the preds by img_id
for pred in preds:
img_id = pred['img_id']
if self.pred_converter is not None:
pred = transform_pred(pred,
self.pred_converter['num_keypoints'],
self.pred_converter['mapping'])
for idx, keypoints in enumerate(pred['keypoints']):
instance = {
'id': pred['id'],
'img_id': pred['img_id'],
'category_id': pred['category_id'],
'keypoints': keypoints,
'keypoint_scores': pred['keypoint_scores'][idx],
'bbox_score': pred['bbox_scores'][idx],
'keypoints_visible': pred['keypoints_visible'][idx],
'keypoint_probs': pred['keypoint_probs'][idx],
'keypoint_oks': pred['keypoint_oks'][idx],
'keypoint_error': pred['keypoint_error'][idx],
}
# breakpoint()
if 'bbox' in pred:
instance['bbox'] = pred['bbox'][idx]
diagonal = np.sqrt(
instance['bbox'][2]**2 + instance['bbox'][3]**2)
if 'areas' in pred:
instance['area'] = pred['areas'][idx]
diagonal = np.sqrt(instance['area'])
else:
# use keypoint to calculate bbox and get area
area = (
np.max(keypoints[:, 0]) - np.min(keypoints[:, 0])) * (
np.max(keypoints[:, 1]) - np.min(keypoints[:, 1]))
instance['area'] = area
diagonal = np.sqrt(area)
kpts[img_id].append(instance)
# sort keypoint results according to id and remove duplicate ones
kpts = self._sort_and_unique_bboxes(kpts, key='id')
# score the prediction results according to `score_mode`
# and perform NMS according to `nms_mode`
valid_kpts = defaultdict(list)
if self.pred_converter is not None:
num_keypoints = self.pred_converter['num_keypoints']
else:
num_keypoints = self.dataset_meta['num_keypoints']
for img_id, instances in kpts.items():
for instance in instances:
# concatenate the keypoint coordinates and scores
instance['keypoints'] = np.concatenate([
instance['keypoints'], instance['keypoint_probs'][:, None]
],
axis=-1)
if self.score_mode == 'bbox':
instance['score'] = instance['bbox_score']
elif self.score_mode == 'keypoint':
instance['score'] = np.mean(instance['keypoint_scores'])
else:
bbox_score = instance['bbox_score']
if self.score_mode == 'bbox_rle':
keypoint_scores = instance['keypoint_scores']
instance['score'] = float(bbox_score +
np.mean(keypoint_scores) +
np.max(keypoint_scores))
else: # self.score_mode == 'bbox_keypoint':
mean_kpt_score = 0
valid_num = 0
for kpt_idx in range(num_keypoints):
kpt_score = instance['keypoint_scores'][kpt_idx]
kpt_prob = instance['keypoint_probs'][kpt_idx]
kpt_thresh = kpt_score if self.score_thresh_type == 'score' else kpt_prob
if kpt_thresh > self.keypoint_score_thr:
mean_kpt_score += kpt_score
valid_num += 1
if valid_num != 0:
mean_kpt_score /= valid_num
instance['score'] = bbox_score * mean_kpt_score
# perform nms
if self.nms_mode == 'none':
valid_kpts[img_id] = instances
else:
nms = oks_nms if self.nms_mode == 'oks_nms' else soft_oks_nms
keep = nms(
instances,
self.nms_thr,
sigmas=self.dataset_meta['sigmas'])
valid_kpts[img_id] = [instances[_keep] for _keep in keep]
# convert results to coco style and dump into a json file
self.results2json(valid_kpts, outfile_prefix=outfile_prefix)
# only format the results without doing quantitative evaluation
if self.format_only:
logger.info('results are saved in '
f'{osp.dirname(outfile_prefix)}')
return {}
eval_results = OrderedDict()
# mAP evaluation results
logger.info(f'Evaluating {self.__class__.__name__}...')
self.prob_thr = 0.51
# Localization evaluation results
info_str = self._do_python_keypoint_eval(outfile_prefix)
name_value = OrderedDict(info_str)
eval_results.update(name_value)
logger.info('Number of values per dataset: {}'.format(len(eval_results)))
if tmp_dir is not None:
tmp_dir.cleanup()
return eval_results
def results2json(self, keypoints: Dict[int, list],
outfile_prefix: str) -> str:
"""Dump the keypoint detection results to a COCO style json file.
Args:
keypoints (Dict[int, list]): Keypoint detection results
of the dataset.
outfile_prefix (str): The filename prefix of the json files. If the
prefix is "somepath/xxx", the json files will be named
"somepath/xxx.keypoints.json",
Returns:
str: The json file name of keypoint results.
"""
# the results with category_id
cat_results = []
for _, img_kpts in keypoints.items():
_keypoints = np.array(
[img_kpt['keypoints'] for img_kpt in img_kpts])
num_keypoints = self.dataset_meta['num_keypoints']
# collect all the person keypoints in current image
_keypoints = _keypoints.reshape(-1, num_keypoints * 3)
result = []
for img_kpt, keypoint in zip(img_kpts, _keypoints):
res = {
'image_id': img_kpt['img_id'],
'category_id': img_kpt['category_id'],
'keypoints': keypoint.tolist(),
'score': float(img_kpt['score']),
}
if 'bbox' in img_kpt:
res['bbox'] = img_kpt['bbox'].tolist()
if 'keypoint_probs' in img_kpt:
res['probs'] = img_kpt['keypoint_probs'].tolist()
result.append(res)
cat_results.extend(result)
res_file = f'{outfile_prefix}.keypoints.json'
dump(cat_results, res_file, sort_keys=True, indent=4)
def _do_python_keypoint_eval(self, outfile_prefix: str) -> list:
"""Do keypoint evaluation using COCOAPI.
Args:
outfile_prefix (str): The filename prefix of the json files. If the
prefix is "somepath/xxx", the json files will be named
"somepath/xxx.keypoints.json",
Returns:
list: a list of tuples. Each tuple contains the evaluation stats
name and corresponding stats value.
"""
res_file = f'{outfile_prefix}.keypoints.json'
coco_det = self.coco.loadRes(res_file)
sigmas = self.dataset_meta['sigmas']
info_str = []
for extended_oks, match_by_bbox, ignore_border_points in zip(
self.extended, self.match_by_bbox, self.ignore_border_points
):
prefix = ""
suffix = ""
if match_by_bbox:
prefix = "bbox_" + prefix
if extended_oks:
prefix = "Ex_" + prefix
if ignore_border_points:
suffix = suffix + "_NoBrd"
conf_thr = self.prob_thr
print("+"*80)
print("COCO Eval params: Bbox {:5s}, ExOKS {:5s}".format(
str(match_by_bbox), str(extended_oks)
), end="")
if extended_oks:
print(" with conf_thr: {:.2f} (has probability: {})".format(conf_thr, self.has_probability), end="")
print()
coco_eval = COCOeval(
self.coco,
coco_det,
iouType=self.iou_type,
sigmas=sigmas,
use_area=self.use_area,
extended_oks=extended_oks,
match_by_bbox=match_by_bbox,
confidence_thr=conf_thr,
padding=self.padding,
ignore_near_bbox=ignore_border_points
)
coco_eval.params.useSegm = None
coco_eval.evaluate()
coco_eval.accumulate()
coco_eval.summarize()
try:
stats_names = coco_eval.stats_names
except AttributeError:
if self.iou_type == 'keypoints_crowd':
stats_names = [
'AP', 'AP .5', 'AP .75', 'AR', 'AR .5', 'AR .75',
'AP(E)', 'AP(M)', 'AP(H)'
]
else:
stats_names = [
'AP', 'AP .5', 'AP .75', 'AP (M)', 'AP (L)', 'AR',
'AR .5', 'AR .75', 'AR (M)', 'AR (L)'
]
i_str = list(zip(stats_names, coco_eval.stats))
ignore_stats = self.ignore_stats
# if match_by_bbox or extended_oks:
# ignore_stats.extend(['AP (M)', 'AP (L)', 'AR (M)', 'AR (L)', 'AR'])
i_str = [(k, v) for k, v in i_str if k not in self.ignore_stats]
i_str = [(f'{prefix}{k}', v) for k, v in i_str]
i_str = [(f'{k}{suffix}', v) for k, v in i_str]
info_str.extend(i_str)
return info_str
def _sort_and_unique_bboxes(self,
kpts: Dict[int, list],
key: str = 'id') -> Dict[int, list]:
"""Sort keypoint detection results in each image and remove the
duplicate ones. Usually performed in multi-batch testing.
Args:
kpts (Dict[int, list]): keypoint prediction results. The keys are
'`img_id`' and the values are list that may contain
keypoints of multiple persons. Each element in the list is a
dict containing the ``'key'`` field.
See the argument ``key`` for details.
key (str): The key name in each person prediction results. The
corresponding value will be used for sorting the results.
Default: ``'id'``.
Returns:
Dict[int, list]: The sorted keypoint detection results.
"""
for img_id, persons in kpts.items():
# deal with bottomup-style output
if isinstance(kpts[img_id][0][key], Sequence):
return kpts
num = len(persons)
kpts[img_id] = sorted(kpts[img_id], key=lambda x: x[key])
for i in range(num - 1, 0, -1):
if kpts[img_id][i][key] == kpts[img_id][i - 1][key]:
del kpts[img_id][i]
return kpts