I'm using TensorFlow to build a deep learning model. And new to TensorFlow.

Due to some reason, my model has limited batch size, then this limited batch-size will make the model has a high variance.

So, I want to use some trick to make the batch size larger. My idea is to store the gradients of each mini-batch, for example 64 mini-batches, and then sum the gradients together, use the mean gradients of this 64 mini batches of training data to update the model's parameters.

This means that for the first 63 mini-batches, do not update the parameters, and after the 64 mini batch, update the model's parameters only once.

But as TensorFlow is graph based, do anyone know how to implement this wanted feature?

Thanks very much.

  • Is the sync replicas optimizer what you're looking for? – Allen Lavoie Feb 10 '17 at 18:54
  • Seems I could store all the middle gradients, and then compute mean of gradients and then update the model parameters. – weixsong Feb 14 '17 at 5:41
  • sync replicas optimizer seems works for multiple GPU parallel training. I will look into it to see if I could leverage it. – weixsong Feb 14 '17 at 5:42

I found a solution here: https://github.com/tensorflow/tensorflow/issues/3994#event-766328647

opt = tf.train.AdamOptimizer()
tvs = tf.trainable_variables()
accum_vars = [tf.Variable(tf.zeros_like(tv.initialized_value()), trainable=False) for tv in tvs]                                        
zero_ops = [tv.assign(tf.zeros_like(tv)) for tv in accum_vars]
gvs = opt.compute_gradients(rmse, tvs)
accum_ops = [accum_vars[i].assign_add(gv[0]) for i, gv in enumerate(gvs)]
train_step = opt.apply_gradients([(accum_vars[i], gv[1]) for i, gv in enumerate(gvs)])

In the training loop:

while True:
    for i in xrange(n_minibatches):
        sess.run(accum_ops, feed_dict=dict(X: Xs[i], y: ys[i]))

But this code seems not very clean and pretty, does anyone know how to optimize these code?

  • Is this possible in keras? – verystrongjoe Apr 25 '18 at 7:49

I had the same problem and just figured it out.

First get symbolic gradients, then define accumulated gradients as tf.Variables. (It seems that tf.global_variables_initializer() has to be run before defining grads_accum. I got errors otherwise, not sure why.)

tvars = tf.trainable_variables()
optimizer = tf.train.GradientDescentOptimizer(lr)
grads = tf.gradients(cost, tvars)

# initialize

grads_accum = [tf.Variable(tf.zeros_like(v)) for v in grads] 
update_op = optimizer.apply_gradients(zip(grads_accum, tvars)) 

In training you can accumulate gradients (saved in gradients_accum) at each batch, and update the model after running the 64-th batch:

feed_dict = dict()
for i, _grads in enumerate(gradients_accum):
    feed_dict[grads_accum[i]] = _grads
sess.run(fetches=[update_op], feed_dict=feed_dict) 

You can refer to tensorflow/tensorflow/python/training/optimizer_test.py for example usage, particularly this function: testGradientsAsVariables().

Hope it helps.

  • I don't think this code is relevant to the question. At what point are the grandients summed up, i.e. accumulated ? Also, in the example you refer to, gradients are not accumulated; they are computed w.r.t. to two inputs independently. – Giorgos Sfikas Oct 24 '17 at 15:36

The previous solutions do not compute the average of the accumulated gradients, which may lead to instability in training. I've modified the above code, which should solve this problem.

# Fetch a list of our network's trainable parameters.
trainable_vars = tf.trainable_variables()

# Create variables to store accumulated gradients
accumulators = [
    ) for tv in trainable_vars

# Create a variable for counting the number of accumulations
accumulation_counter = tf.Variable(0.0, trainable=False)

# Compute gradients; grad_pairs contains (gradient, variable) pairs
grad_pairs = optimizer.compute_gradients(loss, trainable_vars)

# Create operations which add a variable's gradient to its accumulator.
accumulate_ops = [
    ) for (accumulator, (grad, var)) in zip(accumulators, grad_pairs)

# The final accumulation operation is to increment the counter

# Update trainable variables by applying the accumulated gradients
# divided by the counter. Note: apply_gradients takes in a list of 
# (grad, var) pairs
train_step = optimizer.apply_gradients(
    [(accumulator / accumulation_counter, var) \
        for (accumulator, (grad, var)) in zip(accumulators, grad_pairs)]

# Accumulators must be zeroed once the accumulated gradient is applied.
zero_ops = [
    ) for (accumulator, tv) in zip(accumulators, trainable_vars)

# Add one last op for zeroing the counter

This code is used in the same manner as that provided by @weixsong.

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