def validating(self): losses = utils.AverageMeter() self.model.eval() all_dist = [] for i, (inps, tars) in enumerate(self.data_loader): inputs = Variable(inps.cuda()) tars = Variable(tars.cuda(async=True)) outputs = self.model(inputs) # calculate loss outputs_coord = outputs loss = self.loss_fuction(outputs_coord, tars) losses.update(loss.item(), inputs.size(0)) # calculate erruracy targets_unnorm = self.unNormalizeData(tars.data.cpu().numpy(), self.stat_3d['mean'], self.stat_3d['std'], self.stat_3d['dim_use']) outputs_unnorm = self.unNormalizeData(outputs.data.cpu().numpy(), self.stat_3d['mean'], self.stat_3d['std'], self.stat_3d['dim_use']) # remove dim ignored dim_use = np.hstack((np.arange(3), self.stat_3d['dim_use'])) outputs_use = outputs_unnorm[:, dim_use] targets_use = targets_unnorm[:, dim_use] #use procrustes analysis at testing if True: for ba in range(inps.size(0)): gt = targets_use[ba].reshape(-1, 3) out = outputs_use[ba].reshape(-1, 3) _, Z, T, b, c = get_transformation(gt, out, True) out = (b * out.dot(T)) + c outputs_use[ba, :] = out.reshape(1, 51) sqerr = (outputs_use - targets_use)**2 distance = np.zeros((sqerr.shape[0], 17)) dist_idx = 0 for k in np.arange(0, 17 * 3, 3): distance[:, dist_idx] = np.sqrt(np.sum(sqerr[:, k:k + 3], axis=1)) dist_idx += 1 all_dist.append(distance) all_dist = np.vstack(all_dist) #joint_err = np.mean(all_dist, axis=0) ttl_err = np.mean(all_dist) print(">>> error: {} <<<".format(ttl_err)) return losses.avg, ttl_err
def test(test_loader, model, criterion, stat_2d, stat_3d, procrustes=False): losses = utils.AverageMeter() model.eval() all_dist = [] pbar = tqdm(test_loader) for i, (inps, tars) in enumerate(pbar): ### input unnorm data_coord = data_process.unNormalizeData(inps.data.cpu().numpy(), stat_2d['mean'], stat_2d['std'], stat_2d['dim_use']) # 64, 64 dim_2d_use = stat_2d['dim_use'] data_use = data_coord[:, dim_2d_use] # (64, 32) ### input dist norm data_dist_norm, data_dist_set = data_process.input_norm( data_use) # (64, 32) , array data_dist = torch.tensor(data_dist_norm, dtype=torch.float32) # target unnorm label_coord = data_process.unNormalizeData( tars.data.cpu().numpy(), stat_3d['mean'], stat_3d['std'], stat_3d['dim_use']) # (64, 96) dim_3d_use = np.array([ 0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 18, 19, 20, 21, 22, 23, 24, 25, 26, 36, 37, 38, 39, 40, 41, 45, 46, 47, 51, 52, 53, 54, 55, 56, 57, 58, 59, 75, 76, 77, 78, 79, 80, 81, 82, 83 ]) label_use = label_coord[:, dim_3d_use] # (48, ) # target dist norm label_dist_norm, label_dist_set = data_process.output_norm(label_use) label_dist = torch.tensor(label_dist_norm, dtype=torch.float32) inputs = Variable(data_dist.cuda()) targets = Variable(label_dist.cuda(async=True)) outputs = model(inputs) # calculate loss pred_coord = outputs loss = criterion(pred_coord, targets) # 64 losses average losses.update(loss.item(), inputs.size(0)) tars = targets pred = outputs # inputs_dist_set = np.reshape(targets_dist_set, (-1, 1)) # inputs_dist_set = np.repeat(targets_dist_set, 48, axis=1) targets_dist = np.reshape(label_dist_set, (-1, 1)) targets_dist_set = np.repeat(targets_dist, 48, axis=1) c = np.reshape(np.asarray([0, 0, 10]), (1, -1)) c = np.repeat(c, 16, axis=0) c = np.reshape(c, (1, -1)) c = np.repeat(c, inputs.size(0), axis=0) # c_set = np.repeat(np.asarray([0,0,10]), 16, axis=0) #### undist -> unnorm outputs_undist = (pred.data.cpu().numpy() * targets_dist_set) - c # outputs_undist = outputs_undist - c targets_undist = (tars.data.cpu().numpy() * targets_dist_set) - c # targets_undist = targets_undist - c outputs_use = outputs_undist targets_use = targets_undist # (64, 48) if procrustes: for ba in range(inps.size(0)): gt = targets_use[ba].reshape(-1, 3) out = outputs_use[ba].reshape(-1, 3) # (17,3) _, Z, T, b, c = get_transformation(gt, out, True) out = (b * out.dot(T)) + c outputs_use[ba, :] = out.reshape(1, 48) sqerr = (outputs_use - targets_use)**2 # distance = np.zeros((sqerr.shape[0], 17)) distance = np.zeros((sqerr.shape[0], 16)) dist_idx = 0 for k in np.arange(0, 16 * 3, 3): # for k in np.arange(0, 17 * 3, 3): distance[:, dist_idx] = np.sqrt(np.sum(sqerr[:, k:k + 3], axis=1)) dist_idx += 1 all_dist.append(distance) pbar.set_postfix(tt_loss='{:05.6f}'.format(losses.avg)) all_dist = np.vstack(all_dist) joint_err = np.mean(all_dist, axis=0) ttl_err = np.mean(all_dist) # bar.finish() print(">>> error: {} <<<".format(ttl_err)) return losses.avg, ttl_err
def test(test_loader, model, criterion, stat_3d, procrustes=False): losses = utils.AverageMeter() model.eval() all_dist = [] start = time.time() batch_time = 0 bar = Bar(">>>", fill=">", max=len(test_loader)) for i, (inps, tars) in enumerate(test_loader): inputs = Variable(inps.cuda()) targets = Variable(tars.cuda()) outputs = model(inputs) # calculate loss outputs_coord = outputs loss = criterion(outputs_coord, targets) losses.update(loss.item(), inputs.size(0)) tars = targets # calculate erruracy targets_unnorm = data_process.unNormalizeData(tars.data.cpu().numpy(), stat_3d["mean"], stat_3d["std"], stat_3d["dim_use"]) outputs_unnorm = data_process.unNormalizeData( outputs.data.cpu().numpy(), stat_3d["mean"], stat_3d["std"], stat_3d["dim_use"], ) # remove dim ignored dim_use = np.hstack((np.arange(3), stat_3d["dim_use"])) outputs_use = outputs_unnorm[:, dim_use] targets_use = targets_unnorm[:, dim_use] if procrustes: for ba in range(inps.size(0)): gt = targets_use[ba].reshape(-1, 3) out = outputs_use[ba].reshape(-1, 3) _, Z, T, b, c = get_transformation(gt, out, True) out = (b * out.dot(T)) + c outputs_use[ba, :] = out.reshape(1, 51) sqerr = (outputs_use - targets_use)**2 distance = np.zeros((sqerr.shape[0], 17)) dist_idx = 0 for k in np.arange(0, 17 * 3, 3): distance[:, dist_idx] = np.sqrt(np.sum(sqerr[:, k:k + 3], axis=1)) dist_idx += 1 all_dist.append(distance) # update summary if (i + 1) % 100 == 0: batch_time = time.time() - start start = time.time() bar.suffix = "({batch}/{size}) | batch: {batchtime:.4}ms | Total: {ttl} | ETA: {eta:} | loss: {loss:.6f}".format( batch=i + 1, size=len(test_loader), batchtime=batch_time * 10.0, ttl=bar.elapsed_td, eta=bar.eta_td, loss=losses.avg, ) bar.next() all_dist = np.vstack(all_dist) joint_err = np.mean(all_dist, axis=0) ttl_err = np.mean(all_dist) bar.finish() print(">>> error: {} <<<".format(ttl_err)) return losses.avg, ttl_err
def test(test_loader, model, criterion, stat_3d, device, procrustes=False, pck_thresholds=[50, 100, 150, 200, 250], noise_fun=lambda x: x, refine_dic=None, refine_coeff_fun=None, refine_extra_kwargs={}, cache_prefix=None, visualize=False): model.eval() all_outputs = [] all_targets = [] losses = utils.AverageMeter() for i, (inps, tars) in enumerate(test_loader): inps_noise = noise_fun(inps) inputs = Variable(inps_noise.to(device)) targets = Variable(tars.to(device)) outputs = model(inputs) # calculate loss outputs_coord = outputs loss = criterion(outputs_coord, targets) losses.update(loss.item(), inputs.size(0)) tars = targets # calculate erruracy targets_unnorm = data_process.unNormalizeData(tars.data.cpu().numpy(), stat_3d['mean'], stat_3d['std'], stat_3d['dim_use']) outputs_unnorm = data_process.unNormalizeData( outputs.data.cpu().numpy(), stat_3d['mean'], stat_3d['std'], stat_3d['dim_use']) # remove dim ignored dim_use = np.hstack((np.arange(3), stat_3d['dim_use'])) outputs_use = outputs_unnorm[:, dim_use] targets_use = targets_unnorm[:, dim_use] all_outputs.append(outputs_use) all_targets.append(targets_use) accu_frames = np.cumsum(test_loader.dataset.frames) all_outputs = np.split(np.concatenate(all_outputs, axis=0), accu_frames)[:-1] all_targets = np.split(np.concatenate(all_targets, axis=0), accu_frames)[:-1] start = time.time() seq_time = 0 bar = Bar('>>>', fill='>', max=len(all_outputs)) all_dist, all_pck = [], [] for i, (outputs_use, targets_use) in enumerate(zip(all_outputs, all_targets)): if refine_dic is not None: origin = outputs_use outputs_use, _ = ru.refine(outputs_use, refine_dic, refine_coeff_fun, **refine_extra_kwargs) if visualize: visual = [ ru.convert_to_pose_16(seq.reshape([-1, 17, 3])) for seq in [outputs_use, origin, targets_use] ] ru.plot_pose_seq(visual, plot_axis=True, r=1000) if procrustes: for frame in range(outputs_use.shape[0]): gt = targets_use[frame].reshape(-1, 3) out = outputs_use[frame].reshape(-1, 3) _, Z, T, b, c = get_transformation(gt, out, True, reflection=False) out = (b * out.dot(T)) + c outputs_use[frame, :] = out.reshape(1, 51) for pred, gt in zip(outputs_use, targets_use): pred, gt = pred.reshape([-1, 3]), gt.reshape([-1, 3]) all_dist.append(mpjpe_fun(pred, gt)) all_pck.append(pck_fun(pred, gt, thresholds=pck_thresholds)) # update summary seq_time = time.time() - start start = time.time() bar.suffix = '({seq}/{size}) | seq: {seqtime:.4}s | Total: {ttl} | ETA: {eta:} | mpjpe: {loss:.6f}' \ .format(seq=i + 1, size=len(all_outputs), seqtime=seq_time, ttl=bar.elapsed_td, eta=bar.eta_td, loss=np.mean(all_dist)) bar.next() all_dist = np.vstack(all_dist) all_pck = np.array(all_pck) mpjpe = np.mean(all_dist) if cache_prefix: with open('cache/{}_.pkl'.format(cache_prefix), 'wb') as f: pickle.dump({'mpjpe': all_dist, 'pck': all_pck}, f) pck = np.mean(all_pck, axis=0) bar.finish() print(">>> error: {:4f}, pck: {} <<<".format( mpjpe, ' '.join(['{:4f}'.format(val) for val in pck]))) return losses.avg, mpjpe, pck
def test(test_loader, model, criterion, stat_3d, procrustes=False): losses = utils.AverageMeter() model.eval() all_dist = [] # start = time.time() batch_time = 0 bar = Bar('>>>', fill='>', max=len(test_loader)) # test_loader = tqdm(test_loader, dynamic_ncols=True) fig = plt.figure(figsize=(9.6, 5.4))#1920:1080 stat_2d = torch.load(os.path.join(opt.data_dir, 'stat_2d.pth.tar')) # for i, (inps, tars) in enumerate(test_loader): start = time.time() inputs = Variable(inps.cuda()) targets = Variable(tars.cuda(async=True)) outputs, outputs_inputs = model(inputs) # outputs = model(inputs) # print('input:',((inputs)))#16*2 # print('input:',((inputs[0])))#16*2 # print('output:',(len(outputs[0])))#16*3 # print('targets:',(len(targets[0])))#16*3 # calculate loss # ########### # alpha = 0.0 # loss1 = criterion(outputs[0], targets) # loss2 = criterion(outputs[1], targets) # loss = alpha * loss1 + (1.0 - alpha) * loss2 # ######## outputs_coord = outputs loss = criterion(outputs, targets) loss_input = criterion(outputs_inputs, inputs) loss = loss + loss_input losses.update(loss.item(), inputs.size(0)) tars = targets # calculate erruracy #inputs_unnorm = data_process.unNormalizeData(inps.data.cpu().numpy(), stat_2d['mean'], stat_2d['std'], stat_2d['dim_use']) targets_unnorm = data_process.unNormalizeData(tars.data.cpu().numpy(), stat_3d['mean'], stat_3d['std'], stat_3d['dim_use']) outputs_unnorm = data_process.unNormalizeData(outputs.data.cpu().numpy(), stat_3d['mean'], stat_3d['std'], stat_3d['dim_use']) # print(outputs_unnorm.shape[0]) # # print('outputs_unnorm:',((outputs_unnorm)))#16*2 #_max = 0 #_min = 10000 #org_path = r"./data/jsonAlpha_one2/" #filelist = strsort(os.listdir(org_path)) ##print(len(filelist)) #with open(os.path.join(org_path,filelist[i]),encoding='utf8')as fp: # json_data = json.load(fp) #spine_x = json_data['people'][0]['pose_keypoints_2d'][24] #spine_y = json_data['people'][0]['pose_keypoints_2d'][25] #spine_x = spine_x #spine_y = spine_y #print(spine_x) #for k in range(outputs_unnorm.shape[0]): # for j in range(32): # tmp = outputs_unnorm[k][j * 3 + 2] # tmp = z # outputs_unnorm[k][j * 3 + 2] = outputs_unnorm[k][j * 3 + 1]# z = y # outputs_unnorm[k][j * 3 + 1] = tmp # y = z # if outputs_unnorm[k][j * 3 + 2] > _max: # _max = outputs_unnorm[k][j * 3 + 2]# z max # if outputs_unnorm[k][j * 3 + 2] < _min: # _min = outputs_unnorm[k][j * 3 + 2]# z min # #plot出的姿态是倒立的,通过该方法将其校正 #for k in range(outputs_unnorm.shape[0]): # for j in range(32): # outputs_unnorm[k][j * 3 + 2] = _max - outputs_unnorm[k][j * 3 + 2] + _min# z = max-z # outputs_unnorm[k][j * 3] += (spine_x - 630)# x # outputs_unnorm[k][j * 3 + 2] += (500 - spine_y)# z #for k in range(inputs_unnorm.shape[0]): # for j in range(32): # #tmp1 = inputs_unnorm[k][j * 2 + 2] # tmp = z # #inputs_unnorm[k][j * 2 + 2] = inputs_unnorm[k][j * 3 + 1]# z = y # #inputs_unnorm[k][j * 2 + 1] = tmp1 # y = z # if inputs_unnorm[k][j * 2 + 1] > _max: # _max = inputs_unnorm[k][j * 2 + 1]# z max # if inputs_unnorm[k][j * 2 + 1] < _min: # _min = inputs_unnorm[k][j * 2 + 1]# z min # #plot出的姿态是倒立的,通过该方法将其校正 #for k in range(inputs_unnorm.shape[0]): # for j in range(32): # inputs_unnorm[k][j * 2 + 1] = _max - inputs_unnorm[k][j * 2 + 1] + _min# z = max-z # #inputs_unnorm[k][j * 3] += (spine_x - 630)# x # #inputs_unnorm[k][j * 3 + 2] += (500 - spine_y)# z # for k in range(len(outputs_unnorm)): # for j in range(32): # tmp0 = targets_unnorm[k][j * 3 + 2]# tmp = z # targets_unnorm[k][j * 3 + 2] = targets_unnorm[k][j * 3 + 1]# z = y # targets_unnorm[k][j * 3 + 1] = tmp0 # y = z # # tmp = outputs_unnorm[k][j * 3 + 2]# tmp = z # outputs_unnorm[k][j * 3 + 2] = outputs_unnorm[k][j * 3 + 1]# z = y # outputs_unnorm[k][j * 3 + 1] = tmp # y = z # # for k in range(len(outputs_unnorm)): # hip_z0 = targets_unnorm[k][3] # for j in range(32): # targets_unnorm[k][j * 3 + 2] = targets_unnorm[k][j * 3 + 2] - 2*(targets_unnorm[k][j * 3 + 2] - hip_z0) # # hip_z = outputs_unnorm[k][3] # for j in range(32): # outputs_unnorm[k][j * 3 + 2] = outputs_unnorm[k][j * 3 + 2] - 2*(outputs_unnorm[k][j * 3 + 2] - hip_z) #for pp in range(len(outputs_unnorm)): # #ax2 = fig.add_subplot(131) #ax2.get_xaxis().set_visible(False) #ax2.get_yaxis().set_visible(False) #ax2.set_axis_off() #ax2.set_title('Input') #org_path = r"/home/ubuntu/gaoyu/alphapose/Video3D3_cmu/sep-json/" #filelist = strsort(os.listdir(org_path)) #print(filelist[i]) #img2d = imgplt.imread(os.path.join('/home/ubuntu/gaoyu/alphapose/Video3D3_cmu/vis/', '{0}.jpg'.format((filelist[i].split('.')[0]).zfill(12)))) #ax2.imshow(img2d, aspect='equal') # # ax0 = fig.add_subplot(131, projection='3d') # ax0.view_init(0, 300) # viz.show3Dpose( targets_unnorm[pp], ax0, add_labels=True, title = 'GroundTruth') #ax0 = fig.add_subplot(132) #ax0.view_init(0, 300) #viz.show2Dpose( inputs_unnorm[pp]*2.4, ax0, add_labels=True, title = '2DPose Input') #Reconstruction = 1/((time.time() - start)) #start = time.time() #ax1 = fig.add_subplot(133, projection='3d') # # print(len(outputs_unnorm[pp])) #96 #ax1.view_init(0, 300) #默认值30,120 #viz.show3Dpose( outputs_unnorm[pp], ax1, add_labels=True, title = 'Reconstruction: {}FPS'.format(int(Reconstruction))) #plt.pause(0.0000001) #plt.clf() # print('targets_unnorm:',len(outputs_unnorm[0]))#96=32*3 # print('outputs_unnorm:',len(outputs_unnorm[0]))#96=32*3 # remove dim ignored dim_use = np.hstack((np.arange(3), stat_3d['dim_use'])) outputs_use = outputs_unnorm[:, dim_use] targets_use = targets_unnorm[:, dim_use] # print('targets_unnorm:',len(outputs_use[0]))#51=17*3 # print('outputs_unnorm:',len(outputs_use[0]))#51=17*3 if procrustes: for ba in range(inps.size(0)): gt = targets_use[ba].reshape(-1, 3) out = outputs_use[ba].reshape(-1, 3) _, Z, T, b, c = get_transformation(gt, out, True) out = (b * out.dot(T)) + c outputs_use[ba, :] = out.reshape(1, 51) sqerr = (outputs_use - targets_use) ** 2 distance = np.zeros((sqerr.shape[0], 17)) dist_idx = 0 for k in np.arange(0, 17 * 3, 3): distance[:, dist_idx] = np.sqrt(np.sum(sqerr[:, k:k + 3], axis=1)) dist_idx += 1 all_dist.append(distance) # update summary if (i + 1) % 100 == 0: # batch_time = time.time() - start batch_time = 1 # start = time.time() #bar.suffix = '({batch}/{size}) | batch: {batchtime:.4}ms | Total: {ttl} | ETA: {eta:} | loss: {loss:.6f}' \ # .format(batch=i + 1, # size=len(test_loader), # batchtime=batch_time * 10.0, # ttl=bar.elapsed_td, # eta=bar.eta_td, # loss=losses.avg) #bar.next() # test_loader.set_description( '({batch}/{size}) | batch: {batchtime:.4}ms | loss: {loss:.6f}'.format( batch=i + 1, size=len(test_loader), batchtime=batch_time * 10.0, loss=losses.avg) ) test_loader.close() # all_dist = np.vstack(all_dist) joint_err = np.mean(all_dist, axis=0) ttl_err = np.mean(all_dist) # bar.finish() print (">>> error: {} <<<".format(ttl_err)) return losses.avg, ttl_err
def test(test_loader, model, criterion, stat_2d, stat_3d, procrustes=False): losses = utils.AverageMeter() model.eval() all_dist = [] # start = time.time() # batch_time = 0 # bar = Bar('>>>', fill='>', max=len(test_loader)) # for i, (inps, tars) in enumerate(test_loader): pbar = tqdm(test_loader) for i, (inps, tars) in enumerate(pbar): ### input unnorm data_coord = data_process.unNormalizeData(inps.data.cpu().numpy(), stat_2d['mean'], stat_2d['std'], stat_2d['dim_use']) # 64, 64 dim_2d_use = stat_2d['dim_use'] data_use = data_coord[:, dim_2d_use] # (64, 32) ### input dist norm data_dist_norm, data_dist_set = data_process.input_norm( data_use) # (64, 32) , array data_dist = torch.tensor(data_dist_norm, dtype=torch.float32) # target unnorm label_coord = data_process.unNormalizeData( tars.data.cpu().numpy(), stat_3d['mean'], stat_3d['std'], stat_3d['dim_use']) # (64, 96) dim_3d_use = np.array([ 0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 18, 19, 20, 21, 22, 23, 24, 25, 26, 36, 37, 38, 39, 40, 41, 45, 46, 47, 51, 52, 53, 54, 55, 56, 57, 58, 59, 75, 76, 77, 78, 79, 80, 81, 82, 83 ]) label_use = label_coord[:, dim_3d_use] # (48, ) # target dist norm label_dist_norm, label_dist_set = data_process.output_norm(label_use) label_dist = torch.tensor(label_dist_norm, dtype=torch.float32) inputs = Variable(data_dist.cuda()) targets = Variable(label_dist.cuda(async=True)) outputs = model(inputs) # calculate loss pred_coord = outputs loss = criterion(pred_coord, targets) # 64 losses average losses.update(loss.item(), inputs.size(0)) tars = targets pred = outputs # inputs_dist_set = np.reshape(targets_dist_set, (-1, 1)) # inputs_dist_set = np.repeat(targets_dist_set, 48, axis=1) targets_dist = np.reshape(label_dist_set, (-1, 1)) targets_dist_set = np.repeat(targets_dist, 48, axis=1) c = np.reshape(np.asarray([0, 0, 10]), (1, -1)) c = np.repeat(c, 16, axis=0) c = np.reshape(c, (1, -1)) c = np.repeat(c, inputs.size(0), axis=0) # c_set = np.repeat(np.asarray([0,0,10]), 16, axis=0) #### undist -> unnorm outputs_undist = (pred.data.cpu().numpy() * targets_dist_set) - c # outputs_undist = outputs_undist - c targets_undist = (tars.data.cpu().numpy() * targets_dist_set) - c # targets_undist = targets_undist - c ##### '''targets_unnorm : -8095.789092890324, 3447.739184577949, -12287.197684264487, 29496.41833447592, 91899.94409139897, 55478.075331596345, -26361.992715253342, ''' # targets_unnorm = data_process.unNormalizeData(outputs_undist, stat_3d['mean'], stat_3d['std'], # dim_3d_use) # outputs_unnorm = data_process.unNormalizeData(targets_undist, stat_3d['mean'], stat_3d['std'], # dim_3d_use) # inputs_unnorm = data_process.unNormalizeData(inputs.data.cpu().numpy(), stat_2d['mean'], stat_2d['std'], stat_2d['dim_use']) # calculate erruracy # targets_unnorm = data_process.unNormalizeData(tars.data.cpu().numpy(), stat_3d['mean'], stat_3d['std'], stat_3d['dim_use']) # outputs_unnorm = data_process.unNormalizeData(outputs.data.cpu().numpy(), stat_3d['mean'], stat_3d['std'], stat_3d['dim_use']) # remove dim ignored # dim_use = np.hstack((np.arange(3), stat_3d['dim_use'])) # dim_use = dim_3d_use # dim_2d_use = stat_2d['dim_use'] # stat_3d['dim_use'] (48., ) # outputs_use = outputs_unnorm[:, dim_use] # targets_use = targets_unnorm[:, dim_use] # (64, 48) outputs_use = outputs_undist targets_use = targets_undist # (64, 48) # inputs_use = inputs_unnorm[:, dim_2d_use] # (64, 32) if procrustes: for ba in range(inps.size(0)): gt = targets_use[ba].reshape(-1, 3) out = outputs_use[ba].reshape(-1, 3) # (17,3) _, Z, T, b, c = get_transformation(gt, out, True) out = (b * out.dot(T)) + c outputs_use[ba, :] = out.reshape(1, 48) sqerr = (outputs_use - targets_use)**2 # distance = np.zeros((sqerr.shape[0], 17)) distance = np.zeros((sqerr.shape[0], 16)) dist_idx = 0 for k in np.arange(0, 16 * 3, 3): # for k in np.arange(0, 17 * 3, 3): distance[:, dist_idx] = np.sqrt(np.sum(sqerr[:, k:k + 3], axis=1)) dist_idx += 1 all_dist.append(distance) # # update summary # if (i + 1) % 100 == 0: # batch_time = time.time() - start # start = time.time() # # bar.suffix = '({batch}/{size}) | batch: {batchtime:.4}ms | Total: {ttl} | ETA: {eta:} | loss: {loss:.6f}' \ # .format(batch=i + 1, # size=len(test_loader), # batchtime=batch_time * 10.0, # ttl=bar.elapsed_td, # eta=bar.eta_td, # loss=losses.avg) # bar.next() pbar.set_postfix(tt_loss='{:05.6f}'.format(losses.avg)) all_dist = np.vstack(all_dist) joint_err = np.mean(all_dist, axis=0) ttl_err = np.mean(all_dist) # bar.finish() print(">>> error: {} <<<".format(ttl_err)) return losses.avg, ttl_err