30

The documentation is not quite clear about this. I suppose the gradients one can obtain by opt.compute_gradients(E, [v]) contain the ∂E/∂x = g(x) for each element x of the tensor that v stores. Does opt.apply_gradients(grads_and_vars) essentially execute x ← -η·g(x), where η is the learning rate? That would imply that if I want to add a positive additive change p to the variable, I would need to need to change g(x) ← g(x) - (1/η)p, e.g. like this:

opt = tf.train.GradientDescentOptimizer(learning_rate=l)
grads_and_vars = opt.compute_gradients(loss, var_list)

for l, gv in enumerate(grads_and_vars):
    grads_and_vars[l] = (gv[0] - (1/l) * p, gv[1])

train_op = opt.apply_gradients(grads_and_vars)

Is there a better way to do this?

21

The update rule that the apply_gradients method actually applies depends on the specific optimizer. Take a look at the implementation of apply_gradients in the tf.train.Optimizer class here. It relies on the derived classes implementing the update rule in the methods _apply_dense and _apply_spares. The update rule you are referring to is implemented by the GradientDescentOptimizer.

Regarding your desired positive additive update: If what you are calling opt is an instantiation of GradientDescentOptimizer, then you could indeed achieve what you want to do by

grads_and_vars = opt.compute_gradients(E, [v])
eta = opt._learning_rate
my_grads_and_vars = [(g-(1/eta)*p, v) for g, v in grads_and_vars]
opt.apply_gradients(my_grads_and_vars)

The more elegant way to do this is probably to write a new optimizer (inheriting from tf.train.Optimizer) that implements your desired update rule directly.

5
  • Sorry, I overlooked the line opt = tf.train.GradientDescentOptimizer(learning_rate=l) in the code snippet you provided, which makes the first paragraph of my answer somehow irrelevant. Leaving it in for context, nevertheless. – lballes Jun 20 '16 at 12:14
  • Thanks. Other gradient optimizer might calculate e.g. momenta based on my updated gradient, or why would they be incompatible with that approach? – Lenar Hoyt Jun 20 '16 at 12:53
  • Other optimizers implement update rules like gradient descent with momentum, AdaGrad, and so on. Of course, adding a constant value to the update step is compatible with any update rule (how sensible it is being a separate question). – lballes Jun 20 '16 at 13:13
  • What is p? Can you explain (g-(1/eta)*p, v)? – ArtificiallyIntelligence Jan 17 '17 at 5:10
  • @Shaowu, see the question: a positive additive change p – GoingMyWay Jul 7 '17 at 12:26
1

You can also use eager execution API.

import tensorflow as tf
tf.enable_eager_execution()
tfe = tf.contrib.eager
optimizer = tf.train.GradientDescentOptimizer(learning_rate)
grad = tfe.implicit_gradients(loss)
optimizer.apply_gradients(grad(model_fn, val_list))

I will make an instance for it as follow:

import tensorflow as tf
tf.enable_eager_exeuction()
tfe = tf.contrib.eager

W = tfe.Variable(np.random.randn())
b = tfe.Variable(np.random.randn())

def linear_regression(inputs):
    return inputs * W + b;

def MSE(model_fn, inputs, labels):
    return tf.reduce_sum(tf.pow(model_fn(inputs) - labels, 2)) / (2 * n_samples)

optimizer = tf.train.GradientDescentOptimizer(learning_rate = 0.001)
grad = tfe.implicit_gradients(MSE)
optimizer.apply_gradients(grad(linear_regression, train_X, train_Y)) # train_X and train_Y are your input data and label

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