Metadata-Version: 2.1
Name: rdfframes
Version: 0.9.2
Summary: Exposes RDF datasets from sparql endpoints for machine learning models in convenient formats like pandas dataframe
Home-page: https://github.com/qcri/RDFframes
Author: Aisha Mohamed, Ghadeer Abuoda, Zoi Kaoudi, Abdurrahman Ghanem, Ashraf Aboulnaga
Author-email: ahmohamed@qf.org.qa, gabuoda@hbku.edu.qa, zkaoudi@hbku.edu.qa, abghanem@hbku.edu.qa, aaboulnaga@hbku.edu.qa
License: MIT
Platform: UNKNOWN
Classifier: License :: OSI Approved :: MIT License
Classifier: Programming Language :: Python :: 3
Classifier: Programming Language :: Python :: 3.6
Description-Content-Type: text/markdown

# RDFframes


A Python library that enables data scientists to extract data from knowledge graphs encoded in [RDF](https://www.w3.org/TR/2014/REC-rdf11-concepts-20140225/) into familiar tabular formats using familiar procedural Python abstractions.
RDFframes provides an easy-to-use, efficient, and scalable API for users who are familiar with the PyData (Python for Data) ecosystem but are not experts in [SPARQL](https://www.w3.org/TR/sparql11-query/).
The API calls are internally converted into optimized SPARQL queries, which are then executed on a local RDF engine or a remote SPARQL endpoint.
The results are returned in tabular format, such as a pandas dataframe.

## Installation via ``pip``


You can directly install the library via pip by using:

```
 $ pip install RDFframes
```   
## Getting started

First create a ``KnowledgeGraph`` to specify any namespaces that will be used in the query and optionally the graph name and URI.
For example:
```python
graph = KnowledgeGraph(prefixes={
                               "swrc": "http://swrc.ontoware.org/ontology#",
                               "rdf": "http://www.w3.org/1999/02/22-rdf-syntax-ns#",
                               "dc": "http://purl.org/dc/elements/1.1/",
                           })
```

Then create a ``Dataset`` using one of our convenience functions. All the convenience functions are methods in the
```KnowledgeGraph``` class. 
For example, the following code retrieves all instances of the class ``swrc:InProceedings``:

```python
dataset = graph.entities(class_name='swrc:InProceedings',
                             new_dataset_name='papers',
                             entities_col_name='paper')
```

There are two types of datasets: ``ExpandableDataset`` and ``GroupedDataset``. 
An ``ExpandableDataset`` represents a simple flat table, while a ``GroupedDataset`` is a table split into groups as a result of a group-by operation.
The convenience functions on the ``KnowledgeGraph`` return an ``ExpandableDataset``.

After instantiating a dataset, you can use the API to perform operations on it. 
For example, the following code retrieves all authors and titles of conference papers:
```python
dataset = dataset.expand(src_col_name='paper', predicate_list=[
        RDFPredicate('dc:title', 'title'),
        RDFPredicate('dc:creator', 'author'),
        RDFPredicate('swrc:series', 'conference')])\
```

Using the ``group_by`` operation results in a ``GroupedDataset``:
```python
grouped_dataset = dataset.group_by(['author'])
```

Aggregation can be done in both an ``ExpandableDataset`` and ``GroupedDataset``.
For example, the following code counts the number of papers per author and keeps only the authors that have more than 20 papers:
```python
grouped_dataset = grouped_dataset.count(aggregation_fn_data=[AggregationData('paper', 'papers_count')])\
        .filter(conditions_dict={'papers_count': ['>= 20']})
```

## Convenience Functions to create an initial dataset

To create an initial ```Dataset```, you need to use one of the convenience functions. The API 
provides convenience functions that can be used by most of the machine learning and data analytics tasks including:

```python
KnowledgeGraph.classes_and_freq()
```
This function retrieves all the classes in the graph and all the number of instances of each class.
It returns a table of two columns, the first one contains the name of the class and the second one
contains the name of the frequency of the clases.
```python
KnowledgeGraph.features_and_freq(class_name)
```
Retrieves all the features of the instances of the class ```class_name``` and how many instances have each features.
This is critical for many machine learning tasks as knowing how many observed features of entities helps us decide 
on which features to use for.
```python
KnowledgeGraph.entities(class_name)
```
Retrieves all the instances of the class ```class_name```. This is the starting point for most machine 
learning models. The return dataset contains one column of the entities of the specified class and can be
expanded to add features of the instances.
```python
KnowledgeGraph.features(class_name)
```
Retrieves all the features of the class ```class_name```. This function can be used to explore the dataset and learn
what features are available in the data for a specific class.
```python
KnowledgeGraph.entities_and_features(class_name, features, )
```
Retrieves all instances of the class ```class_name``` and the features of the instances specified in the list 
```features```.
```python
KnowledgeGraph.num_entities(class_name)
```
Returns the number of instances of the class ```class_name``` in the dataset.
```python
KnowledgeGraph.feature_domain_range(feature)
```
Returieves the domain (subjects) and the range (objects) of the predicate ```feature``` occuring in the dataset.
```python
KnowledgeGraph.describe_entity(entity)
```
Returns the class and features of the entity.





