https://github.com/GPflow/GPflow
Tip revision: 1342c286e4c704b0e718e15a6e1d4c194ce0c076 authored by Alexander G. de G. Matthews on 04 January 2018, 11:15:29 UTC
Merge pull request #607 from GPflow/awav/awav-backward-tensors
Merge pull request #607 from GPflow/awav/awav-backward-tensors
Tip revision: 1342c28
decors.py
# Copyright 2017 Artem Artemev @awav
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
import functools
import contextlib
import tensorflow as tf
from .core.errors import GPflowError
from .core.compilable import Build
from .core.compilable import AutoBuildStatus
from .core.node import Node
from .core.autoflow import AutoFlow
from .core.tensor_converter import TensorConverter
from .params import Parameterized
def name_scope(name=None):
"""
Name scope decorator does little trick with scope naming. The wrapped
function will be run inside TensorFlow name scope with name specified
by either `name` option or `name` option is None then name of the
function will be used.
"""
def name_scope_wrapper(method):
@functools.wraps(method)
def runnable(*args, **kwargs):
scope_name = name if name is not None else method.__name__
with tf.name_scope(scope_name):
return method(*args, **kwargs)
return runnable
return name_scope_wrapper
def params_as_tensors(method):
"""
The `params_as_tensors` decorator converts representation for parameters into
their unconstrained tensors, and data holders to their data tensors inside
wrapped function, subject to this function is a member of parameterized object.
"""
@functools.wraps(method)
def tensor_mode_wrapper(obj, *args, **kwargs):
if not isinstance(obj, Parameterized):
raise GPflowError(
'Tensor mode works only for Parameterized object.')
prev_value = _params_as_tensors_enter(obj, True)
try:
result = method(obj, *args, **kwargs)
finally:
_params_as_tensors_exit(obj, prev_value)
return result
return tensor_mode_wrapper
class defer_build(contextlib.ContextDecorator):
"""
The `defer_build` can be either context manager or decorator. In both cases it
cancels autobuild feature for all gpflow ICompilable objects. Sometimes,
it is require to build model with aligned names or for some other reasons.
Example below shows that `defer_build` allows you to create kernel and
change parameters in it without running into an exception that the model
has already been changed.
```
X = np.linspace(-3,3,20)
Y = np.random.exponential(np.sin(X)**2)
with gpflow.defer_build():
k = gpflow.kernels.Matern32(1, ARD=False) + gpflow.kernels.Bias(1)
l = gpflow.likelihoods.Exponential()
m = gpflow.models.GPMC(X, Y, k, l)
m.kern.matern32.lengthscales.prior = gpflow.priors.Gamma(1., 1.)
m.kern.matern32.variance.prior = gpflow.priors.Gamma(1., 1.)
m.kern.bias.variance.prior = gpflow.priors.Gamma(1., 1.)
...
m.compile()
```
:param defer: Option to control defer mechanics. If `defer` is `False` AutoBuild
feature will as usual.
"""
def __init__(self, defer=True):
self.disable_build = not defer
self.prev_autobuild_status = None
def __enter__(self):
self.prev_autobuild_status = AutoBuildStatus.__autobuild_enabled_global__
AutoBuildStatus.__autobuild_enabled_global__ = self.disable_build
def __exit__(self, *exc):
AutoBuildStatus.__autobuild_enabled_global__ = self.prev_autobuild_status
return False
@contextlib.contextmanager
def params_as_tensors_for(obj, convert=True):
"""
Context manager which changes respresentation of parameters and data holders
for specific parameterized object.
User can turn off tensor conversion inside `params_as_tensors` wrapped function.
```
@gpflow.params_as_tensors
def compute_something(self): # self is parameterized object.
s = tf.reduce_sum(self.a) # self.a is a parameter.
with params_as_tensors_for(self, convert=False):
b = self.c.constrained_tensor
return s + b
```
:param convert: Flag which is used for turning tensor convertion
feature on, `True`, or turning it off, `False`.
"""
prev_value = _params_as_tensors_enter(obj, convert)
try:
yield
finally:
_params_as_tensors_exit(obj, prev_value)
def autoflow(*af_args, **af_kwargs):
def autoflow_wrapper(method):
@functools.wraps(method)
def runnable(obj, *args, **kwargs):
if not isinstance(obj, Node):
raise GPflowError(
'AutoFlow works only with node-like objects.')
if obj.is_built_coherence(obj.graph) is Build.NO:
raise GPflowError('Not built with "{graph}".'.format(graph=obj.graph))
name = method.__name__
store = AutoFlow.get_autoflow(obj, name)
session = kwargs.pop('session', None)
session = obj.enquire_session(session=session)
scope_name = _name_scope_name(obj, name)
with session.graph.as_default(), tf.name_scope(scope_name):
if not store:
_setup_storage(store, *af_args, **af_kwargs)
_build_method(method, obj, store)
return _session_run(session, obj, store, *args, **kwargs)
return runnable
return autoflow_wrapper
def _params_as_tensors_enter(obj, convert=True):
name = TensorConverter.__tensor_mode__
attr_value = getattr(obj, name, None)
setattr(obj, name, convert)
return attr_value
def _params_as_tensors_exit(obj, previous):
name = TensorConverter.__tensor_mode__
if previous is not None:
setattr(obj, name, previous)
else:
delattr(obj, name)
def _setup_storage(store, *args, **_kwargs):
store['arguments'] = [tf.placeholder(*arg) for arg in args]
def _name_scope_name(obj, name):
return '/'.join(['autoflow', obj.name, name])
def _session_run(session, obj, store, *args, **kwargs):
feed_dict_key = 'feed_dict'
if feed_dict_key not in kwargs:
kwargs[feed_dict_key] = {}
feed_dict = kwargs.get(feed_dict_key)
feed_dict.update(dict(zip(store['arguments'], args)))
if obj.feeds:
feed_dict.update(obj.feeds)
initialize = kwargs.pop('initialize', False)
obj.initialize(session=session, force=initialize)
return session.run(store['result'], **kwargs)
def _build_method(method, obj, store):
store['result'] = method(obj, *store['arguments'])