BigML makes machine learning easy by taking care of the details required to add data-driven decisions and predictive power to your company. Unlike other machine learning services, BigML creates beautiful predictive models that can be easily understood and interacted with.
These BigML Python bindings allow you to interact with BigML.io, the API for BigML. You can use it to easily create, retrieve, list, update, and delete BigML resources (i.e., sources, datasets, models and, predictions). For additional information, see the full documentation for the Python bindings on Read the Docs.
This module is licensed under the Apache License, Version 2.0.
Please report problems and bugs to our BigML.io issue tracker.
Discussions about the different bindings take place in the general BigML mailing list. Or join us in our Campfire chatroom.
Only Python 3
versions are currently supported by these bindings.
Support for Python 2.7.X ended in version 4.32.3
.
The basic third-party dependencies are the requests, unidecode, requests-toolbelt, bigml-chronos, msgpack, numpy and scipy libraries. These libraries are automatically installed during the basic setup. Support for Google App Engine has been added as of version 3.0.0, using the urlfetch package instead of requests.
The bindings will also use simplejson
if you happen to have it
installed, but that is optional: we fall back to Python's built-in JSON
libraries is simplejson
is not found.
The bindings provide support to use the BigML
platform to create, update,
get and delete resources, but also to produce local predictions using the
models created in BigML
. Most of them will be actionable with the basic
installation, but some additional dependencies are needed to use local
Topic Models
and Image Processing models. Please, refer to the
Installation section for details.
The basic installation of the bindings is compatible and can be used
on Linux and Windows based Operating Systems.
However, the extra options that allow working with
image processing models ([images]
and [full]
) are only supported
and tested on Linux-based Operating Systems.
For image models, Windows OS is not recommended and cannot be supported out of
the box, because the specific compiler versions or dlls required are
unavailable in general.
To install the basic latest stable release with pip, please use:
$ pip install bigml
Support for local Topic Distributions (Topic Models' predictions) and local predictions for datasets that include Images will only be available as extras, because the libraries used for that are not usually available in all Operative Systems. If you need to support those, please check the Installation Extras section.
Local Topic Distributions support can be installed using:
pip install bigml[topics]
Images local predictions support can be installed using:
pip install bigml[images]
The full set of features can be installed using:
pip install bigml[full]
WARNING: Mind that installing these extras can require some extra work, as explained in the Requirements section.
You can also install the development version of the bindings directly from the Git repository
$ pip install -e git://github.com/bigmlcom/python.git#egg=bigml_python
The tests will be run using pytest.
You'll need to set up your authentication
via environment variables, as explained
in the authentication section. Also some of the tests need other environment
variables like BIGML_ORGANIZATION
to test calls when used by Organization
members and BIGML_EXTERNAL_CONN_HOST
, BIGML_EXTERNAL_CONN_PORT
,
BIGML_EXTERNAL_CONN_DB
, BIGML_EXTERNAL_CONN_USER
,
BIGML_EXTERNAL_CONN_PWD
and BIGML_EXTERNAL_CONN_SOURCE
in order to test external data connectors.
With that in place, you can run the test suite simply by issuing
$ pytest
Additionally, Tox can be used to automatically run the test suite in virtual environments for all supported Python versions. To install Tox:
$ pip install tox
Then run the tests from the top-level project directory:
$ tox
To import the module:
import bigml.api
Alternatively you can just import the BigML class:
from bigml.api import BigML
All the requests to BigML.io must be authenticated using your username and API key and are always transmitted over HTTPS.
This module will look for your username and API key in the environment
variables BIGML_USERNAME
and BIGML_API_KEY
respectively.
You can
add the following lines to your .bashrc
or .bash_profile
to set
those variables automatically when you log in:
export BIGML_USERNAME=myusername
export BIGML_API_KEY=ae579e7e53fb9abd646a6ff8aa99d4afe83ac291
refer to the next chapters to know how to do that in other operating systems.
With that environment set up, connecting to BigML is a breeze:
from bigml.api import BigML
api = BigML()
Otherwise, you can initialize directly when instantiating the BigML class as follows:
api = BigML('myusername', 'ae579e7e53fb9abd646a6ff8aa99d4afe83ac291')
These credentials will allow you to manage any resource in your user environment.
In BigML a user can also work for an organization
.
In this case, the organization administrator should previously assign
permissions for the user to access one or several particular projects
in the organization.
Once permissions are granted, the user can work with resources in a project
according to his permission level by creating a special constructor for
each project. The connection constructor in this case
should include the project ID
:
api = BigML('myusername', 'ae579e7e53fb9abd646a6ff8aa99d4afe83ac291',
project='project/53739b98d994972da7001d4a')
If the project used in a connection object does not belong to an existing organization but is one of the projects under the user's account, all the resources created or updated with that connection will also be assigned to the specified project.
When the resource to be managed is a project
itself, the connection
needs to include the corresponding``organization ID``:
api = BigML('myusername', 'ae579e7e53fb9abd646a6ff8aa99d4afe83ac291',
organization='organization/53739b98d994972da7025d4a')
The credentials should be permanently stored in your system using
setx BIGML_USERNAME myusername
setx BIGML_API_KEY ae579e7e53fb9abd646a6ff8aa99d4afe83ac291
Note that setx
will not change the environment variables of your actual
console, so you will need to open a new one to start using them.
You can set the environment variables using the %env
command in your
cells:
%env BIGML_USERNAME=myusername
%env BIGML_API_KEY=ae579e7e53fb9abd646a6ff8aa99d4afe83ac291
The main public domain for the API service is bigml.io
, but there are some
alternative domains, either for Virtual Private Cloud setups or
the australian subdomain (au.bigml.io
). You can change the remote
server domain
to the VPC particular one by either setting the BIGML_DOMAIN
environment
variable to your VPC subdomain:
export BIGML_DOMAIN=my_VPC.bigml.io
or setting it when instantiating your connection:
api = BigML(domain="my_VPC.bigml.io")
The corresponding SSL REST calls will be directed to your private domain henceforth.
You can also set up your connection to use a particular PredictServer
only for predictions. In order to do so, you'll need to specify a Domain
object, where you can set up the general domain name as well as the
particular prediction domain name.
from bigml.domain import Domain
from bigml.api import BigML
domain_info = Domain(prediction_domain="my_prediction_server.bigml.com",
prediction_protocol="http")
api = BigML(domain=domain_info)
Finally, you can combine all the options and change both the general domain server, and the prediction domain server.
from bigml.domain import Domain
from bigml.api import BigML
domain_info = Domain(domain="my_VPC.bigml.io",
prediction_domain="my_prediction_server.bigml.com",
prediction_protocol="https")
api = BigML(domain=domain_info)
Some arguments for the Domain constructor are more unsual, but they can also be used to set your special service endpoints:
- protocol (string) Protocol for the service (when different from HTTPS)
- verify (boolean) Sets on/off the SSL verification
- prediction_verify (boolean) Sets on/off the SSL verification for the prediction server (when different from the general SSL verification)
Note that the previously existing dev_mode
flag:
api = BigML(dev_mode=True)
that caused the connection to work with the Sandbox Development Environment
has been deprecated because this environment does not longer exist.
The existing resources that were previously
created in this environment have been moved
to a special project in the now unique Production Environment
, so this
flag is no longer needed to work with them.
Imagine that you want to use this csv
file containing the Iris
flower dataset to
predict the species of a flower whose petal length
is 2.45
and
whose petal width
is 1.75
. A preview of the dataset is shown
below. It has 4 numeric fields: sepal length
, sepal width
,
petal length
, petal width
and a categorical field: species
.
By default, BigML considers the last field in the dataset as the
objective field (i.e., the field that you want to generate predictions
for).
sepal length,sepal width,petal length,petal width,species 5.1,3.5,1.4,0.2,Iris-setosa 4.9,3.0,1.4,0.2,Iris-setosa 4.7,3.2,1.3,0.2,Iris-setosa ... 5.8,2.7,3.9,1.2,Iris-versicolor 6.0,2.7,5.1,1.6,Iris-versicolor 5.4,3.0,4.5,1.5,Iris-versicolor ... 6.8,3.0,5.5,2.1,Iris-virginica 5.7,2.5,5.0,2.0,Iris-virginica 5.8,2.8,5.1,2.4,Iris-virginica
You can easily generate a prediction following these steps:
from bigml.api import BigML
api = BigML()
source = api.create_source('./data/iris.csv')
dataset = api.create_dataset(source)
model = api.create_model(dataset)
prediction = api.create_prediction(model, \
{"petal width": 1.75, "petal length": 2.45})
You can then print the prediction using the pprint
method:
>>> api.pprint(prediction)
species for {"petal width": 1.75, "petal length": 2.45} is Iris-setosa
Certainly, any of the resources created in BigML can be configured using
several arguments described in the API documentation.
Any of these configuration arguments can be added to the create
method
as a dictionary in the last optional argument of the calls:
from bigml.api import BigML
api = BigML()
source_args = {"name": "my source",
"source_parser": {"missing_tokens": ["NULL"]}}
source = api.create_source('./data/iris.csv', source_args)
dataset_args = {"name": "my dataset"}
dataset = api.create_dataset(source, dataset_args)
model_args = {"objective_field": "species"}
model = api.create_model(dataset, model_args)
prediction_args = {"name": "my prediction"}
prediction = api.create_prediction(model, \
{"petal width": 1.75, "petal length": 2.45},
prediction_args)
The iris
dataset has a small number of instances, and usually will be
instantly created, so the api.create_
calls will probably return the
finished resources outright. As BigML's API is asynchronous,
in general you will need to ensure
that objects are finished before using them by using api.ok
.
from bigml.api import BigML
api = BigML()
source = api.create_source('./data/iris.csv')
api.ok(source)
dataset = api.create_dataset(source)
api.ok(dataset)
model = api.create_model(dataset)
api.ok(model)
prediction = api.create_prediction(model, \
{"petal width": 1.75, "petal length": 2.45})
Note that the prediction
call is not followed by the api.ok
method. Predictions are so quick to be
generated that, unlike the
rest of resouces, will be generated synchronously as a finished object.
The example assumes that your objective field (the one you want to predict)
is the last field in the dataset. If that's not he case, you can explicitly
set the name of this field in the creation call using the objective_field
argument:
from bigml.api import BigML
api = BigML()
source = api.create_source('./data/iris.csv')
api.ok(source)
dataset = api.create_dataset(source)
api.ok(dataset)
model = api.create_model(dataset, {"objective_field": "species"})
api.ok(model)
prediction = api.create_prediction(model, \
{'sepal length': 5, 'sepal width': 2.5})
You can also generate an evaluation for the model by using:
test_source = api.create_source('./data/test_iris.csv')
api.ok(test_source)
test_dataset = api.create_dataset(test_source)
api.ok(test_dataset)
evaluation = api.create_evaluation(model, test_dataset)
api.ok(evaluation)
If you set the storage
argument in the api
instantiation:
api = BigML(storage='./storage')
all the generated, updated or retrieved resources will be automatically saved to the chosen directory.
Alternatively, you can use the export
method to explicitly
download the JSON information
that describes any of your resources in BigML to a particular file:
api.export('model/5acea49a08b07e14b9001068',
filename="my_dir/my_model.json")
This example downloads the JSON for the model and stores it in
the my_dir/my_model.json
file.
In the case of models that can be represented in a PMML syntax, the export method can be used to produce the corresponding PMML file.
api.export('model/5acea49a08b07e14b9001068',
filename="my_dir/my_model.pmml",
pmml=True)
You can also retrieve the last resource with some previously given tag:
api.export_last("foo",
resource_type="ensemble",
filename="my_dir/my_ensemble.json")
which selects the last ensemble that has a foo
tag. This mechanism can
be specially useful when retrieving retrained models that have been created
with a shared unique keyword as tag.
For a descriptive overview of the steps that you will usually need to follow to model your data and obtain predictions, please see the basic Workflow sketch document. You can also check other simple examples in the following documents:
- model 101
- logistic regression 101
- linear regression 101
- ensemble 101
- cluster 101
- anomaly detector 101
- association 101
- topic model 101
- deepnet 101
- time series 101
- fusion 101
- scripting 101
We've just barely scratched the surface. For additional information, see
the full documentation for the Python
bindings on Read the Docs.
Alternatively, the same documentation can be built from a local checkout
of the source by installing Sphinx
($ pip install sphinx
) and then running
$ cd docs
$ make html
Then launch docs/_build/html/index.html
in your browser.
Please follow the next steps:
- Fork the project on github.com.
- Create a new branch.
- Commit changes to the new branch.
- Send a pull request.
For details on the underlying API, see the BigML API documentation.