예제 #1
0
def run_test(net,
             data_root,
             exp_name,
             work_dir,
             griding_num,
             use_aux,
             distributed,
             batch_size=8):
    # torch.backends.cudnn.benchmark = True
    output_path = os.path.join(work_dir, exp_name)
    if not os.path.exists(output_path) and is_main_process():
        os.mkdir(output_path)
    synchronize()
    loader = get_test_loader(batch_size, data_root, 'CULane', distributed)
    # import pdb;pdb.set_trace()
    for i, data in enumerate(dist_tqdm(loader)):
        imgs, names = data
        imgs = imgs.cuda()
        with torch.no_grad():
            out = net(imgs)
        if len(out) == 2 and use_aux:
            out, seg_out = out

        generate_lines(out,
                       imgs[0, 0].shape,
                       names,
                       output_path,
                       griding_num,
                       localization_type='rel',
                       flip_updown=True)
예제 #2
0
def eval_lane(net, dataset, data_root, work_dir, griding_num, use_aux, distributed):
    net.eval()
    if dataset == 'CULane':
        run_test(net,data_root, 'culane_eval_tmp', work_dir, griding_num, use_aux, distributed)
        synchronize()   # wait for all results
        if is_main_process():
            res = call_culane_eval(data_root, 'culane_eval_tmp', work_dir)
            TP,FP,FN = 0,0,0
            for k, v in res.items():
                val = float(v['Fmeasure']) if 'nan' not in v['Fmeasure'] else 0
                val_tp,val_fp,val_fn = int(v['tp']),int(v['fp']),int(v['fn'])
                TP += val_tp
                FP += val_fp
                FN += val_fn
                dist_print(k,val)
            P = TP * 1.0/(TP + FP)
            R = TP * 1.0/(TP + FN)
            F = 2*P*R/(P + R)
            dist_print(F)
        synchronize()

    elif dataset == 'Tusimple':
        exp_name = 'tusimple_eval_tmp'
        run_test_tusimple(net, data_root, work_dir, exp_name, griding_num, use_aux, distributed)
        synchronize()  # wait for all results
        if is_main_process():
            combine_tusimple_test(work_dir,exp_name)
            res = LaneEval.bench_one_submit(os.path.join(work_dir,exp_name + '.txt'),os.path.join(data_root,'test_label.json'))
            res = json.loads(res)
            for r in res:
                dist_print(r['name'], r['value'])
        synchronize()
예제 #3
0
def eval_lane(net, dataset, data_root, work_dir, distributed, cfg):
    net.eval()
    run_test(net, data_root, 'culane_eval_tmp', work_dir, distributed, cfg)
    synchronize()  # wait for all results
    if is_main_process():
        res = call_culane_eval(data_root, 'culane_eval_tmp', work_dir)
        TP, FP, FN = 0, 0, 0
        for k, v in res.items():
            val = float(v['Fmeasure']) if 'nan' not in v['Fmeasure'] else 0
            val_tp, val_fp, val_fn = int(v['tp']), int(v['fp']), int(v['fn'])
            TP += val_tp
            FP += val_fp
            FN += val_fn
            dist_print(k, val)
        P = TP * 1.0 / (TP + FP)
        R = TP * 1.0 / (TP + FN)
        F = 2 * P * R / (P + R)
        dist_print(F)
    synchronize()
예제 #4
0
def run_test(net,
             data_root,
             exp_name,
             work_dir,
             distributed,
             cfg,
             batch_size=1):
    # torch.backends.cudnn.benchmark = True
    output_path = os.path.join(work_dir, exp_name)
    if not os.path.exists(output_path) and is_main_process():
        os.mkdir(output_path)
    synchronize()

    row_anchor = np.linspace(90, 255, 128).tolist()
    col_sample = np.linspace(0, 1640 - 1, 256)
    col_sample_w = col_sample[1] - col_sample[0]

    loader = get_test_loader(batch_size, data_root, 'CULane', distributed)

    filter_f = lambda x: int(np.round(x))

    # import pdb;pdb.set_trace()
    for i, data in enumerate(dist_tqdm(loader)):
        imgs, names = data
        imgs = imgs.cuda()
        with torch.no_grad():
            out = net(imgs)

        for j in range(len(names)):
            name = names[j]

            line_save_path = os.path.join(output_path, name[:-3] + 'lines.txt')
            save_dir, _ = os.path.split(line_save_path)
            if not os.path.exists(save_dir):
                os.makedirs(save_dir)
            with open(line_save_path, 'w') as writer:
                lane_exit_out = out["lane_exit_out"].sigmoid()
                lane_exit_out = lane_exit_out > cfg.thresh_lc

                for lane_index in range(lane_exit_out.size(1)):
                    if lane_exit_out[0][lane_index] == True:
                        x_list = []
                        y_list = []
                        vertex_wise_confidence_out = out[
                            "vertex_wise_confidence_out_" +
                            str(lane_index + 1)].sigmoid()
                        vertex_wise_confidence_out = vertex_wise_confidence_out > cfg.thresh_vc

                        row_wise_vertex_location_out = F.log_softmax(
                            out["row_wise_vertex_location_out_" +
                                str(lane_index + 1)],
                            dim=0)
                        row_wise_vertex_location_out = torch.argmax(
                            row_wise_vertex_location_out, dim=0)
                        row_wise_vertex_location_out[
                            ~vertex_wise_confidence_out] = 256

                        row_wise_vertex_location_out = row_wise_vertex_location_out.detach(
                        ).cpu().numpy()

                        estimator = RANSACRegressor(random_state=42,
                                                    min_samples=2,
                                                    residual_threshold=10.0)
                        ##model = make_pipeline(PolynomialFeatures(2), estimator)

                        for k in range(row_wise_vertex_location_out.shape[0]):
                            if row_wise_vertex_location_out[k] != 256:
                                x = row_wise_vertex_location_out[
                                    k] * col_sample_w
                                y = row_anchor[k] / 256 * 590
                                x_list.append(x)
                                y_list.append(y)
                                #writer.write('%d %d ' % (filter_f(row_wise_vertex_location_out[k] * col_sample_w), filter_f(row_anchor[k] / 256 * 590)))
                        #writer.write('\n')

                        if len(x_list) <= 1:
                            continue
                        X = np.array(x_list)
                        y = np.array(y_list)
                        y = y[:, np.newaxis]
                        y_plot = np.linspace(y.min(), y.max())
                        estimator.fit(y, X)
                        x_plot = estimator.predict(y_plot[:, np.newaxis])

                        for x, y in zip(x_plot, y_plot):
                            writer.write('%d %d ' % (filter_f(x), filter_f(y)))
                        writer.write('\n')