Fuel: Difference between revisions
From charlesreid1
No edit summary |
|||
| Line 35: | Line 35: | ||
Datasets are the principal interface to data. Internally, they use a DataStream object to create and request iterators. | Datasets are the principal interface to data. Internally, they use a DataStream object to create and request iterators. | ||
===Example=== | ===Datasets Example=== | ||
Suppose we create eight (8) different 2x2 greyscale images, and put them in the variable "features", then create 4 target classes, and put them in "targets": | Suppose we create eight (8) different 2x2 greyscale images, and put them in the variable "features", then create 4 target classes, and put them in "targets": | ||
| Line 172: | Line 172: | ||
In [21]: dataset.close(state=state) | In [21]: dataset.close(state=state) | ||
</pre> | </pre> | ||
=Wrapping Custom Datasets with Fuel= | =Wrapping Custom Datasets with Fuel= | ||
Revision as of 20:34, 14 October 2017
Basics
Fuel is a library for creating machine learning data pipelines. There are multiple features that make it really convenient.
Find fuel on Github here: https://github.com/mila-udem/fuel
Overview of how it works: https://fuel.readthedocs.io/en/latest/overview.html
Prerequisites
Fuel uses HDF5, so you will need a copy of HDF5 header files installed locally. Use your package manager, or follow HDF5 installation instructions. On a Mac:
$ brew install hdf5
Now you can install Fuel.
Install
$ git clone git@github.com:/mila-udem/fuel.git $ cd fuel $ python setup.py build && python setup.py install
Basic Usage
Datasets
Datasets are the principal interface to data. Internally, they use a DataStream object to create and request iterators.
Datasets Example
Suppose we create eight (8) different 2x2 greyscale images, and put them in the variable "features", then create 4 target classes, and put them in "targets":
In [1]: import numpy In [2]: seed = 1234 In [3]: rng = numpy.random.RandomState(seed) In [4]: features = rng.randint(256, size=(8, 2, 2)) In [5]: targets = rng.randint(4, size=(8, 1))
Now we can create a Dataset to iterate over the data:
In [6]: from collections import OrderedDict
In [7]: from fuel.datasets import IterableDataset
In [8]: dataset = IterableDataset(
...: iterables=OrderedDict([('features', features), ('targets', targets)]),
...: axis_labels=OrderedDict([('features', ('batch', 'height', 'width')),
...: ('targets', ('batch', 'index'))]))
and we can access each attribute using the dataset object:
In [9]: print('Provided sources are {}.'.format(dataset.provides_sources))
Provided sources are ('features', 'targets').
In [10]: print('Sources are {}.'.format(dataset.sources))
Sources are ('features', 'targets').
In [11]: print('Axis labels are {}.'.format(dataset.axis_labels))
Axis labels are OrderedDict([('features', ('batch', 'height', 'width')), ('targets', ('batch', 'index'))]).
In [12]: print('Dataset contains {} examples.'.format(dataset.num_examples))
Dataset contains 8 examples.
In [14]: from pprint import pprint
In [15]: pprint(dir(dataset))
['__abstractmethods__',
'__class__',
'__delattr__',
'__dict__',
'__dir__',
'__doc__',
'__eq__',
'__format__',
'__ge__',
'__getattribute__',
'__gt__',
'__hash__',
'__init__',
'__init_subclass__',
'__le__',
'__lt__',
'__module__',
'__ne__',
'__new__',
'__reduce__',
'__reduce_ex__',
'__repr__',
'__setattr__',
'__sizeof__',
'__str__',
'__subclasshook__',
'__weakref__',
'_abc_cache',
'_abc_negative_cache',
'_abc_negative_cache_version',
'_abc_registry',
'apply_default_transformers',
'axis_labels',
'close',
'default_transformers',
'example_iteration_scheme',
'filter_sources',
'get_data',
'get_example_stream',
'iterables',
'next_epoch',
'num_examples',
'open',
'provides_sources',
'reset',
'sources']
Note that the dataset is stateless, so we need to create an external object to represent the state, then pass that into the dataset when we want to iterate over/access the data:
In [17]: state = dataset.open()
In [18]: while True:
...: try:
...: print(dataset.get_data(state=state))
...: except StopIteration:
...: print('Iterator finished')
...: break
...:
(array([[ 47, 211],
[ 38, 53]]), array([0]))
(array([[204, 116],
[152, 249]]), array([3]))
(array([[143, 177],
[ 23, 233]]), array([0]))
(array([[154, 30],
[171, 158]]), array([1]))
(array([[236, 124],
[ 26, 118]]), array([2]))
(array([[186, 120],
[112, 220]]), array([2]))
(array([[ 69, 80],
[201, 127]]), array([2]))
(array([[246, 254],
[175, 50]]), array([3]))
Iterator finished
To reset the state, use the Dataset object's reset() function. To finish, use the close() function.
In [19]: state = dataset.reset(state=state)
In [20]: print(dataset.get_data(state=state))
(array([[ 47, 211],
[ 38, 53]]), array([0]))
In [21]: dataset.close(state=state)
Wrapping Custom Datasets with Fuel
Repo by github user dribnet illustrates how to wrap a new dataset using Fuel: https://github.com/dribnet/lfw_fuel
Advantages:
- Only takes one command to download the data and import it into fuel
- Then it only takes one command to import the library that wraps the data, and be able to turn it into training/testing X and Y
Disadvantages:
- One-size-fits-all; importing data using load_data() can take a REALLY long time, and must be done every time you run the script (not persistent in memory)
- Complicated to extend
- Removes some of the nicer options of fuel
Here is what the final payoff looks like:
from keras.models import Sequential from lfw_fuel import lfw # the data, shuffled and split between train and test sets (X_train, y_train), (X_test, y_test) = lfw.load_data(format="deepfunneled") # (build the perfect model here) model.fit(X_train, Y_train, show_accuracy=True, validation_data=(X_test, Y_test)) score = model.evaluate(X_test, Y_test, show_accuracy=True, verbose=0)