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开源软件名称(OpenSource Name):deepmind/sonnet开源软件地址(OpenSource Url):https://github.com/deepmind/sonnet开源编程语言(OpenSource Language):Python 95.9%开源软件介绍(OpenSource Introduction):SonnetSonnet is a library built on top of TensorFlow 2 designed to provide simple, composable abstractions for machine learning research. IntroductionSonnet has been designed and built by researchers at DeepMind. It can be used to construct neural networks for many different purposes (un/supervised learning, reinforcement learning, ...). We find it is a successful abstraction for our organization, you might too! More specifically, Sonnet provides a simple but powerful programming model
centered around a single concept: Unlike many frameworks Sonnet is extremely unopinionated about how you will use your modules. Modules are designed to be self contained and entirely decoupled from one another. Sonnet does not ship with a training framework and users are encouraged to build their own or adopt those built by others. Sonnet is also designed to be simple to understand, our code is (hopefully!) clear and focussed. Where we have picked defaults (e.g. defaults for initial parameter values) we try to point out why. Getting StartedExamplesThe easiest way to try Sonnet is to use Google Colab which offers a free Python notebook attached to a GPU or TPU.
InstallationTo get started install TensorFlow 2.0 and Sonnet 2: $ pip install tensorflow tensorflow-probability
$ pip install dm-sonnet You can run the following to verify things installed correctly: import tensorflow as tf
import sonnet as snt
print("TensorFlow version {}".format(tf.__version__))
print("Sonnet version {}".format(snt.__version__)) Using existing modulesSonnet ships with a number of built in modules that you can trivially use. For
example to define an MLP we can use the mlp = snt.Sequential([
snt.Linear(1024),
tf.nn.relu,
snt.Linear(10),
]) To use our module we need to "call" it. The logits = mlp(tf.random.normal([batch_size, input_size])) It is also very common to request all the parameters for your module. Most modules in Sonnet create their parameters the first time they are called with some input (since in most cases the shape of the parameters is a function of the input). Sonnet modules provide two properties for accessing parameters. The all_variables = mlp.variables It is worth noting that model_parameters = mlp.trainable_variables Building your own moduleSonnet strongly encourages users to subclass class MyLinear(snt.Module):
def __init__(self, output_size, name=None):
super(MyLinear, self).__init__(name=name)
self.output_size = output_size
@snt.once
def _initialize(self, x):
initial_w = tf.random.normal([x.shape[1], self.output_size])
self.w = tf.Variable(initial_w, name="w")
self.b = tf.Variable(tf.zeros([self.output_size]), name="b")
def __call__(self, x):
self._initialize(x)
return tf.matmul(x, self.w) + self.b Using this module is trivial: mod = MyLinear(32)
mod(tf.ones([batch_size, input_size])) By subclassing >>> print(repr(mod))
MyLinear(output_size=10) You also get the >>> mod.variables
(<tf.Variable 'my_linear/b:0' shape=(10,) ...)>,
<tf.Variable 'my_linear/w:0' shape=(1, 10) ...)>) You may notice the Additionally your module will now support TensorFlow checkpointing and saved model which are advanced features covered later. SerializationSonnet supports multiple serialization formats. The simplest format we support
is Python's TensorFlow CheckpointingReference: https://www.tensorflow.org/alpha/guide/checkpoints TensorFlow checkpointing can be used to save the value of parameters periodically during training. This can be useful to save the progress of training in case your program crashes or is stopped. Sonnet is designed to work cleanly with TensorFlow checkpointing: checkpoint_root = "/tmp/checkpoints"
checkpoint_name = "example"
save_prefix = os.path.join(checkpoint_root, checkpoint_name)
my_module = create_my_sonnet_module() # Can be anything extending snt.Module.
# A `Checkpoint` object manages checkpointing of the TensorFlow state associated
# with the objects passed to it's constructor. Note that Checkpoint supports
# restore on create, meaning that the variables of `my_module` do **not** need
# to be created before you restore from a checkpoint (their value will be
# restored when they are created).
checkpoint = tf.train.Checkpoint(module=my_module)
# Most training scripts will want to restore from a checkpoint if one exists. This
# would be the case if you interrupted your training (e.g. to use your GPU for
# something else, or in a cloud environment if your instance is preempted).
latest = tf.train.latest_checkpoint(checkpoint_root)
if latest is not None:
checkpoint.restore(latest)
for step_num in range(num_steps):
train(my_module)
# During training we will occasionally save the values of weights. Note that
# this is a blocking call and can be slow (typically we are writing to the
# slowest storage on the machine). If you have a more reliable setup it might be
# appropriate to save less frequently.
if step_num and not step_num % 1000:
checkpoint.save(save_prefix)
# Make sure to save your final values!!
checkpoint.save(save_prefix) TensorFlow Saved ModelReference: https://www.tensorflow.org/alpha/guide/saved_model TensorFlow saved models can be used to save a copy of your network that is decoupled from the Python source for it. This is enabled by saving a TensorFlow graph describing the computation and a checkpoint containing the value of weights. The first thing to do in order to create a saved model is to create a
my_module = snt.nets.MLP([1024, 1024, 10])
my_module(tf.ones([1, input_size])) Next, we need to create another module describing the specific parts of our model that we want to export. We advise doing this (rather than modifying the original model in-place) so you have fine grained control over what is actually exported. This is typically important to avoid creating very large saved models, and such that you only share the parts of your model you want to (e.g. you only want to share the generator for a GAN but keep the discriminator private). @tf.function(input_signature=[tf.TensorSpec([None, input_size])])
def inference(x):
return my_module(x)
to_save = snt.Module()
to_save.inference = inference
to_save.all_variables = list(my_module.variables)
tf.saved_model.save(to_save, "/tmp/example_saved_model") We now have a saved model in the $ ls -lh /tmp/example_saved_model
total 24K
drwxrwsr-t 2 tomhennigan 154432098 4.0K Apr 28 00:14 assets
-rw-rw-r-- 1 tomhennigan 154432098 14K Apr 28 00:15 saved_model.pb
drwxrwsr-t 2 tomhennigan 154432098 4.0K Apr 28 00:15 variables Loading this model is simple and can be done on a different machine without any of the Python code that built the saved model: loaded = tf.saved_model.load("/tmp/example_saved_model")
# Use the inference method. Note this doesn't run the Python code from `to_save`
# but instead uses the TensorFlow Graph that is part of the saved model.
loaded.inference(tf.ones([1, input_size]))
# The all_variables property can be used to retrieve the restored variables.
assert len(loaded.all_variables) > 0 Note that the loaded object is not a Sonnet module, it is a container object
that has the specific methods (e.g. Distributed trainingExample: https://github.com/deepmind/sonnet/blob/v2/examples/distributed_cifar10.ipynb Sonnet has support for distributed training using custom TensorFlow distribution strategies. A key difference between Sonnet and distributed training using Our distributed Cifar-10 example walks through doing multi-GPU training with Sonnet. |
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