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I was training Bidirectional LSTM type RNN for nearly 24 hours, and due to oscillation in the error I decided to decrease the learning before allowing it to continue training. Since the model is saved using Saver.save(sess,file) at every epoch, I terminated the training with the CTC Loss having minimised to approximately 115.

Now after restoring the model, the initial error rate I am getting is somewhere around 162, which is inconsistent with the flow of error rate I was getting in 7th epoch, and is also what I got in the first epoch. So it is my impression that either "restore" function is not working or if it is working, then there must be something else that is not allowing it to take effect.

Here is my code:

    graph = tf.Graph()
    with graph.as_default():
        # Graph creation
        graph_start = time.time()
        seq_inputs = tf.placeholder(tf.float32, shape=     [None,batch_size,frame_length], name="sequence_inputs")
        seq_lens = tf.placeholder(shape=[batch_size],dtype=tf.int32)
        seq_inputs = seq_bn(seq_inputs,seq_lens)

        initializer = tf.truncated_normal_initializer(mean=0,stddev=0.1)
        forward = tf.nn.rnn_cell.LSTMCell(num_units=num_units,
                                          num_proj = hidden_size,
                                          use_peepholes=use_peephole,
                                          initializer=initializer,
                                          state_is_tuple=True)

        forward = tf.nn.rnn_cell.MultiRNNCell([forward] * n_layers, state_is_tuple=True)

        backward = tf.nn.rnn_cell.LSTMCell(num_units=num_units,
                                           num_proj= hidden_size,
                                           use_peepholes=use_peephole,
                                           initializer=initializer,
                                           state_is_tuple=True)

        backward = tf.nn.rnn_cell.MultiRNNCell([backward] * n_layers, state_is_tuple=True)

        [fw_out,bw_out], _ = tf.nn.bidirectional_dynamic_rnn(cell_fw=forward, cell_bw=backward, inputs=seq_inputs,time_major=True, dtype=tf.float32,                                               sequence_length=tf.cast(seq_lens,tf.int64))


        # Batch normalize forward output
        mew,var_ = tf.nn.moments(fw_out,axes=[0])
        fw_out = tf.nn.batch_normalization(fw_out,mew,var_,0.1,1,1e-6)
        # fw_out = seq_bn(fw_out,seq_lens)

        # Batch normalize backward output
        mew,var_ = tf.nn.moments(bw_out,axes=[0])
        bw_out = tf.nn.batch_normalization(bw_out,mew,var_,0.1,1,1e-6)
        # bw_out = seq_bn(bw_out,seq_lens)

        # Reshaping forward, and backward outputs for affine transformation
        fw_out = tf.reshape(fw_out,[-1,hidden_size])
        bw_out = tf.reshape(bw_out,[-1,hidden_size])

        # Linear Layer params
        W_fw = tf.Variable(tf.truncated_normal(shape=[hidden_size,n_chars],stddev=np.sqrt(2.0 / (hidden_size))))
        W_bw = tf.Variable(tf.truncated_normal(shape=[hidden_size,n_chars],stddev=np.sqrt(2.0 / (hidden_size))))
        b_out = tf.constant(0.1,shape=[n_chars])

        # Perform an affine transformation
        logits =  tf.add(tf.add(tf.matmul(fw_out,W_fw),tf.matmul(bw_out,W_bw)),b_out)
        logits = tf.reshape(logits,[-1,batch_size,n_chars])

        # Use CTC Beam Search Decoder to decode pred string from the prob map
        decoded, log_prob = tf.nn.ctc_beam_search_decoder(logits, seq_lens)

        # Target params
        indices = tf.placeholder(dtype=tf.int64, shape=[None,2])
        values = tf.placeholder(dtype=tf.int32, shape=[None])
        shape = tf.placeholder(dtype=tf.int64,shape=[2])
        # Make targets
        targets = tf.SparseTensor(indices,values,shape)

        # Compute Loss
        loss = tf.reduce_mean(tf.nn.ctc_loss(logits, targets, seq_lens))
        # Compute error rate based on edit distance
        predicted = tf.to_int32(decoded[0])
        error_rate = tf.reduce_sum(tf.edit_distance(predicted,targets,normalize=False))/ \
         tf.to_float(tf.size(targets.values))    

        tvars = tf.trainable_variables()
        grad, _ = tf.clip_by_global_norm(tf.gradients(loss,tvars),max_grad_norm)
        optimizer = tf.train.MomentumOptimizer(learning_rate=lr,momentum=momentum)
        train_step = optimizer.apply_gradients(zip(grad,tvars))
        graph_end = time.time()
        print("Time elapsed for creating graph: %.3f"%(round(graph_end-graph_start,3)))
        # steps per epoch
        start_time = 0
        steps = int(np.ceil(len(data_train.files)/batch_size))

        loss_tr = []
        log_tr = []
        loss_vl = []
        log_vl = []
        err_tr = []
        err_vl = []
        saver = tf.train.Saver()
        with tf.Session(config=config) as sess:
            #sess.run(tf.initialize_all_variables())
            checkpt_path = tf.train.latest_checkpoint(checkpoint_dir)
            print(saver.restore(sess,checkpt_path))
            print("Model restore from 7th epoch 188th step")
            feed = None
            epoch = None
            step = None
            try:
                for epoch in range(7,epochs+1):
                    if epoch==7:
                       initial_step = 189
                    else:
                       initial_step = 0
                    transcript = []
                    loss_val = 0
                    l_pr = 0
                    start_time = time.time()
                    for step in range(initial_step,steps):
                        train_data, transcript, \
                        targ_indices, targ_values, \
                        targ_shape, n_frames = data_train.next_batch()
                        n_frames = np.reshape(n_frames,[-1])
                        feed = {seq_inputs: train_data, indices:targ_indices, values:targ_values, shape:targ_shape, seq_lens:n_frames}
                        del train_data,targ_indices,targ_values,targ_shape,n_frames

                        # Evaluate loss value, decoded transcript, and log probability
                        _,loss_val,deco,l_pr,err_rt_tr = sess.run([train_step,loss,decoded,log_prob,error_rate],
                                                            feed_dict=feed)
                        del feed
                        loss_tr.append(loss_val)
                        log_tr.append(l_pr)
                        err_tr.append(err_rt_tr)

                        # On validation set
                        val_data, val_transcript, \
                        targ_indices, targ_values, \
                        targ_shape, n_frames = data_val.next_batch()
                        n_frames = np.reshape(n_frames, [-1])
                        feed = {seq_inputs: val_data, indices: targ_indices,values: targ_values, shape: targ_shape, seq_lens: n_frames}
                        del val_data, val_transcript,targ_indices,targ_values,targ_shape,n_frames
                    vl_loss, l_val_pr, err_rt_vl = sess.run([loss, log_prob, error_rate], feed_dict=feed)
                        del feed
                        loss_vl.append(vl_loss)
                        log_vl.append(l_val_pr)
                        err_vl.append(err_rt_vl)
                        print("epoch %d, step: %d, tr_loss: %.2f, vl_loss: %.2f, tr_err: %.2f, vl_err: %.2f"
                          % (epoch, step, np.mean(loss_tr), np.mean(loss_vl), err_rt_tr, err_rt_vl))

                    end_time = time.time()
                    elapsed = round(end_time - start_time, 3)

                    # On training set
                    # Select a random index within batch_size
                    sample_index = np.random.randint(0, batch_size)

                    # Fetch the target transcript
                    actual_str = [data_train.reverse_map[i] for i in transcript[sample_index]]

                    # Fetch the decoded path from probability map
                    pred_sparse = tf.SparseTensor(deco[0].indices, deco[0].values, deco[0].shape)
                    pred_dense = tf.sparse_tensor_to_dense(pred_sparse)
                    ans = pred_dense.eval()
                    #pred = [data_train.reverse_map[i] for i in ans[sample_index, :]]
                    pred = []
                    for i in ans[sample_index,:]:
                        if i == n_chars-1:
                            pred.append(data_train.reverse_map[0])
                        else:
                            pred.append(data_train.reverse_map[i])
                    print("time_elapsed for 200 steps: %.3f, " % (elapsed))
                    if epoch%2 == 0:
                        print("Sample mini-batch results: \n" \
                              "predicted string: ", np.array(pred))
                        print("actual string: ", np.array(actual_str))
                    print("On training set, the loss: %.2f, log_pr: %.3f, error rate %.3f:"% (loss_val, np.mean(l_pr), err_rt_tr))
                    print("On validation set, the loss: %.2f, log_pr: %.3f, error rate: %.3f" % (vl_loss, np.mean(l_val_pr), err_rt_vl))

                    # Save the trainable parameters after the end of an epoch
                    if epoch > 7:
                        path = saver.save(sess, 'model_%d' % epoch)
                    print("Session saved at: %s" % path)
                    np.save(results_fn, np.array([loss_tr, log_tr, loss_vl, log_vl, err_tr, err_vl], dtype=np.object))
            except (KeyboardInterrupt, SystemExit, Exception), e:
                print("Error/Interruption: %s" % str(e))
                exc_type, exc_obj, exc_tb = sys.exc_info()
                print("Line no: %d" % exc_tb.tb_lineno)
                if epoch > 7:
                    print("Saving model: %s" % saver.save(sess, 'Last.cpkt'))
                print("Current batch: %d" % data_train.b_id)
                print("Current epoch: %d" % epoch)
                print("Current step: %d"%step)
                np.save(results_fn, np.array([loss_tr, log_tr, loss_vl, log_vl, err_tr, err_vl], dtype=np.object))
                print("Clossing TF Session...")
                sess.close()
                print("Terminating Program...")
                sys.exit(0)
  • if you are not running initialize_all_variables, then restore must be getting all the variables from checkpoints (or you'd get uninitialized variable error) – Yaroslav Bulatov Aug 10 '16 at 18:11
  • btw, a common pattern to early detect these kinds of checkpoint problems is to do evaluation in parallel in a different process, concurrently with the main program – Yaroslav Bulatov Aug 10 '16 at 18:18
  • @YaroslavBulatov I initially had the call statement to restore after initialising variables, but in some blog I read that it is not necessary that the variables need to be initialised when restoring from checkpoint, hence I commented it. I am not getting any error, the program is working fine. My concern is it is probably NOT restoring the model parameters to the state it is saved in file since I am getting training error rate I got in the first epoch. – VM_AI Aug 10 '16 at 18:43
  • @VM_AI I have the same problem, have you found a solution? – King Long Tse Dec 26 '16 at 0:38
  • Do you save your lr and momentum? – Sergey Jun 23 '17 at 17:05
0

I think you need to re-initialize your accumulators for each epoch.

So these ones must be put at the beginning, inside the loop.

loss_tr = []
log_tr = []
loss_vl = []
log_vl = []
err_tr = []
err_vl = []

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