コード例 #1
0
ファイル: evaluate.py プロジェクト: tonivu28/eval-kit
    def evaluate(self) -> Tuple[DetectionMetrics, DetectionMetricDataList]:
        """
        Performs the actual evaluation.
        :return: A tuple of high-level and the raw metric data.
        """
        start_time = time.time()

        # -----------------------------------
        # Step 1: Accumulate metric data for all classes and distance thresholds.
        # -----------------------------------
        if self.verbose:
            print('Accumulating metric data...')
        metric_data_list = DetectionMetricDataList()
        for class_name in self.cfg.class_names:
            for dist_th in self.cfg.dist_ths:
                md, instance_dict = accumulate(self.gt_boxes, self.pred_boxes,
                                               class_name,
                                               self.cfg.dist_fcn_callable,
                                               dist_th, False,
                                               self.is_average_delay)
                metric_data_list.set(class_name, dist_th, md)

        # -----------------------------------
        # Step 2: Calculate metrics from the data.
        # -----------------------------------
        if self.verbose:
            print('Calculating metrics...')
        metrics = DetectionMetrics(self.cfg)
        for class_name in self.cfg.class_names:
            # Compute APs.
            for dist_th in self.cfg.dist_ths:
                metric_data = metric_data_list[(class_name, dist_th)]
                ap = calc_ap(metric_data, self.cfg.min_recall,
                             self.cfg.min_precision)
                metrics.add_label_ap(class_name, dist_th, ap)

            # Compute TP metrics.
            for metric_name in TP_METRICS:
                metric_data = metric_data_list[(class_name,
                                                self.cfg.dist_th_tp)]
                if class_name in ['traffic_cone'] and metric_name in [
                        'attr_err', 'vel_err', 'orient_err'
                ]:
                    tp = np.nan
                elif class_name in ['barrier'] and metric_name in [
                        'attr_err', 'vel_err'
                ]:
                    tp = np.nan
                else:
                    tp = calc_tp(metric_data, self.cfg.min_recall, metric_name)
                metrics.add_label_tp(class_name, metric_name, tp)

        # Compute evaluation time.
        metrics.add_runtime(time.time() - start_time)

        return metrics, metric_data_list
コード例 #2
0
    def run(self) -> Tuple[DetectionMetrics, MetricDataList]:

        start_time = time.time()

        # -----------------------------------
        # Step 1: Accumulate metric data for all classes and distance thresholds
        # -----------------------------------

        metric_data_list = MetricDataList()
        for class_name in self.cfg.class_names:
            for dist_th in self.cfg.dist_ths:
                md = accumulate(self.gt_boxes, self.pred_boxes, class_name,
                                self.cfg.dist_fcn, dist_th)
                metric_data_list.set(class_name, dist_th, md)

        # -----------------------------------
        # Step 2: Calculate metrics from the data
        # -----------------------------------

        metrics = DetectionMetrics(self.cfg)
        for class_name in self.cfg.class_names:
            for dist_th in self.cfg.dist_ths:
                metric_data = metric_data_list[(class_name, dist_th)]
                ap = calc_ap(metric_data, self.cfg.min_recall,
                             self.cfg.min_precision)
                metrics.add_label_ap(class_name, dist_th, ap)

            for metric_name in TP_METRICS:
                metric_data = metric_data_list[(class_name,
                                                self.cfg.dist_th_tp)]
                if class_name in ['traffic_cone'] and metric_name in [
                        'attr_err', 'vel_err', 'orient_err'
                ]:
                    tp = np.nan
                elif class_name in ['barrier'] and metric_name in [
                        'attr_err', 'vel_err'
                ]:
                    tp = np.nan
                else:
                    tp = calc_tp(metric_data, self.cfg.min_recall, metric_name)
                metrics.add_label_tp(class_name, metric_name, tp)

        metrics.add_runtime(time.time() - start_time)

        # -----------------------------------
        # Step 3: Dump the metric data and metrics to disk
        # -----------------------------------

        with open(os.path.join(self.output_dir, 'metrics.json'), 'w') as f:
            json.dump(metrics.serialize(), f, indent=2)

        with open(os.path.join(self.output_dir, 'metric_data_list.json'),
                  'w') as f:
            json.dump(metric_data_list.serialize(), f, indent=2)

        return metrics, metric_data_list
コード例 #3
0
def eval_main(root_path, info_path, version, res_path, eval_set, output_dir):

    cfg = config_factory()
    result_path = res_path
    # Check result file exists.
    assert os.path.exists(
        result_path), 'Error: The result file does not exist!'
    # Make dirs.
    if not os.path.isdir(output_dir):
        os.makedirs(output_dir)
    # Load data.
    print('Initializing nuScenes detection evaluation')
    pred_boxes, meta = load_prediction(result_path,
                                       cfg.max_boxes_per_sample,
                                       DetectionBox,
                                       verbose=True)
    gt_boxes = load_gt(root_path,
                       info_path,
                       eval_set,
                       DetectionBox,
                       verbose=True)

    assert set(pred_boxes.sample_tokens) == set(gt_boxes.sample_tokens), \
        "Samples in split doesn't match samples in predictions."
    """
    Performs the actual evaluation.
    :return: A tuple of high-level and the raw metric data.
    """
    start_time = time.time()
    verbose = True
    # -----------------------------------
    # Step 1: Accumulate metric data for all classes and distance thresholds.
    # -----------------------------------
    if verbose:
        print('Accumulating metric data...')
    metric_data_list = DetectionMetricDataList()
    for class_name in cfg.class_names:
        for dist_th in cfg.dist_ths:
            md = accumulate(gt_boxes, pred_boxes, class_name,
                            cfg.dist_fcn_callable, dist_th)
            metric_data_list.set(class_name, dist_th, md)

    # -----------------------------------
    # Step 2: Calculate metrics from the data.
    # -----------------------------------
    if verbose:
        print('Calculating metrics...')
    metrics = DetectionMetrics(cfg)
    for class_name in cfg.class_names:
        # Compute APs.
        for dist_th in cfg.dist_ths:
            metric_data = metric_data_list[(class_name, dist_th)]
            ap = calc_ap(metric_data, cfg.min_recall, cfg.min_precision)
            metrics.add_label_ap(class_name, dist_th, ap)

        # Compute TP metrics.
        for metric_name in TP_METRICS:
            metric_data = metric_data_list[(class_name, cfg.dist_th_tp)]
            tp = calc_tp(metric_data, cfg.min_recall, metric_name)
            metrics.add_label_tp(class_name, metric_name, tp)

    # Compute evaluation time.
    metrics.add_runtime(time.time() - start_time)

    # Dump the metric data, meta and metrics to disk.
    if verbose:
        print('Saving metrics to: %s' % output_dir)
    metrics_summary = metrics.serialize()
    metrics_summary['meta'] = meta.copy()
    with open(os.path.join(output_dir, 'metrics_summary.json'), 'w') as f:
        json.dump(metrics_summary, f, indent=2)
    with open(os.path.join(output_dir, 'metrics_details.json'), 'w') as f:
        json.dump(metric_data_list.serialize(), f, indent=2)

    # Print high-level metrics.
    print('mAP: %.4f' % (metrics_summary['mean_ap']))
    err_name_mapping = {
        'trans_err': 'mATE',
        'scale_err': 'mASE',
        'orient_err': 'mAOE',
        'vel_err': 'mAVE',
        'attr_err': 'mAAE'
    }
    for tp_name, tp_val in metrics_summary['tp_errors'].items():
        print('%s: %.4f' % (err_name_mapping[tp_name], tp_val))
    print('NDS: %.4f' % (metrics_summary['nd_score']))
    print('Eval time: %.1fs' % metrics_summary['eval_time'])

    # Print per-class metrics.
    print()
    print('Per-class results:')
    print('Object Class\tAP\tATE\tASE\tAOE\tAVE\tAAE')
    class_aps = metrics_summary['mean_dist_aps']
    class_tps = metrics_summary['label_tp_errors']
    for class_name in class_aps.keys():
        print('%s\t%.3f\t%.3f\t%.3f\t%.3f\t%.3f\t%.3f' %
              (class_name, class_aps[class_name],
               class_tps[class_name]['trans_err'],
               class_tps[class_name]['scale_err'],
               class_tps[class_name]['orient_err'],
               class_tps[class_name]['vel_err'],
               class_tps[class_name]['attr_err']))