Pretty Tensor provides a high level builder API for TensorFlow. It provides thin wrappers on Tensors so that you can easily build multi-layer neural networks.
Pretty Tensor provides a set of objects that behave likes Tensors, but also support a chainable object syntax to quickly define neural networks and other layered architectures in TensorFlow.
result = (pretty_tensor.wrap(input_data, m)
.flatten()
.fully_connected(200, activation_fn=tf.nn.relu)
.fully_connected(10, activation_fn=None)
.softmax(labels, name=softmax_name))
Please look here for full documentation of the PrettyTensor object for all available operations: Available Operations or you can check out the complete documentation
See the tutorial directory for samples: tutorial/
The easiest installation is just to use pip:
pip install prettytensor
Note: Head is tested against the TensorFlow nightly builds and pip is tested against TensorFlow release.
import prettytensor as pt
import tensorflow as tf
my_inputs = # numpy array of shape (BATCHES, BATCH_SIZE, DATA_SIZE)
my_labels = # numpy array of shape (BATCHES, BATCH_SIZE, CLASSES)
input_tensor = tf.placeholder(np.float32, shape=(BATCH_SIZE, DATA_SIZE))
label_tensor = tf.placeholder(np.float32, shape=(BATCH_SIZE, CLASSES))
pretty_input = pt.wrap(input_tensor)
softmax, loss = (pretty_input.
fully_connected(100).
softmax_classifier(CLASSES, labels=label_tensor))
accuracy = softmax.evaluate_classifier(label_tensor)
optimizer = tf.train.GradientDescentOptimizer(0.1) # learning rate
train_op = pt.apply_optimizer(optimizer, losses=[loss])
init_op = tf.initialize_all_variables()
with tf.Session() as sess:
sess.run(init_op)
for inp, label in zip(my_inputs, my_labels):
unused_loss_value, accuracy_value = sess.run([loss, accuracy],
{input_tensor: inp, label_tensor: label})
print 'Accuracy: %g' % accuracy_value
Pretty Tensors can be used (almost) everywhere that a tensor can. Just call
pt.wrap
to make a tensor pretty.
You can also add any existing TensorFlow function to the chain using apply
.
apply
applies the current Tensor as the first argument and takes all the other
arguments as normal.
Note: because apply is so generic, Pretty Tensor doesn't try to wrap the world.
It also uses standard TensorFlow idioms so that it plays well with other libraries, this means that you can use it a little bit in a model or throughout. Just make sure to run the update_ops on each training set (see with_update_ops).
You've already seen how a Pretty Tensor is chainable and you may have noticed that it takes care of handling the input shape. One other feature worth noting are defaults. Using defaults you can specify reused values in a single place without having to repeat yourself.
with pt.defaults_scope(activation_fn=tf.nn.relu):
hidden_output2 = (pretty_images.flatten()
.fully_connected(100)
.fully_connected(100))
Check out the documentation to see all supported defaults.
Sequential mode lets you break model construction across lines and provides the subdivide syntactic sugar that makes it easy to define and understand complex structures like an inception module:
with pretty_tensor.defaults_scope(activation_fn=tf.nn.relu):
seq = pretty_input.sequential()
with seq.subdivide(4) as towers:
towers[0].conv2d(1, 64)
towers[1].conv2d(1, 112).conv2d(3, 224)
towers[2].conv2d(1, 32).conv2d(5, 64)
towers[3].max_pool(2, 3).conv2d(1, 32)
Templates provide guaranteed parameter reuse and make unrolling recurrent networks easy:
output = [], s = tf.zeros([BATCH, 256 * 2])
A = (pretty_tensor.template('x')
.lstm_cell(num_units=256, state=UnboundVariable('state'))
for x in pretty_input_array:
h, s = A.construct(x=x, state=s)
output.append(h)
There are also some convenient shorthands for LSTMs and GRUs:
pretty_input_array.sequence_lstm(num_units=256)
You can call any existing operation by using apply
and it will simply
subsitute the current tensor for the first argument.
pretty_input.apply(tf.mul, 5)
You can also create a new operation There are two supported registration
mechanisms to add your own functions. @Register()
allows you to create a
method on PrettyTensor that operates on the Tensors and returns either a loss or
a new value. Name scoping and variable scoping are handled by the framework.
The following method adds the leaky_relu method to every Pretty Tensor:
@pt.Register
def leaky_relu(input_pt):
return tf.select(tf.greater(input_pt, 0.0), input_pt, 0.01 * input_pt)
@RegisterCompoundOp()
is like adding a macro, it is designed to group together
common sets of operations.
Within a graph, you can reuse variables by using templates. A template is just like a regular graph except that some variables are left unbound.
See more details in PrettyTensor class.
Pretty Tensor uses the standard graph collections from TensorFlow to store variables. These can be accessed using tf.get_collection(key)
with the following keys:
tf.GraphKeys.VARIABLES
: all variables that should be saved (including some statistics).tf.GraphKeys.TRAINABLE_VARIABLES: all variables that can be trained (including those before a
stop_gradients` call). These are what would typically be called parameters of the model in ML parlance.pt.GraphKeys.TEST_VARIABLES
: variables used to evaluate a model. These are typically not saved and are reset by the LocalRunner.evaluate method to get a fresh evaluation.Eider Moore (eiderman)
with key contributions from: