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AlgebraicRelations.jl

Tests

AlgebraicRelations.jl is a Julia library built to provide an intuitive and elegant method for generating and querying a scientific database. This package provides tooling for defining database schemas, generating query visualizations, and connecting directly up to a PostgreSQL server. This package is built on top of Catlab.jl which is the powerhouse behind its functions.

Learning by Doing

The functions of this library may be best explained by showing an example of how it can be used. This will be done in the steps of Defining a Schema, Creating Queries, and Connecting to PostgreSQL.

Defining a Schema

Within this library, we define database schemas based on the presentation of a workflow (more generally, the presentation of a symmetric monoidal category). The presentation of a workflow includes the data types of products in the workflow (objects in an SMC) and the processes that transform these products (homomorphisms in an SMC). We will give an example of defining the schema of a traditional computer vision workflow. This involves extracting images from a file, performing a test/train split on images, training a neural network on images, and finally evaluating a network on images. This example is also presented in this notebook.

Defining Types

In order to define types for the presentation, we need to provide the name of the type (e.g. File for compressed files of images) and then the Julia datatype which can store this type (The filename can be stored uniquely as a String). The definition of all types that we will need for our example is as follows:

# Initialize presentation object
present = Presentation()

# Add types to presentation
File, Images, NeuralNet,
Accuracy, Metadata = add_types!(present, [(:File, String),
                                          (:Images, String),
                                          (:NeuralNet, String),
                                          (:Accuracy, Real),
                                          (:Metadata, String)]);

Defining Processes

To define processes that operate on these types, we need three pieces of information. First, we need the name of the processes (extract for the process that extracts images from files), the input types (File for the file to extract) and the output types (Images for the images which were extracted). The symbol (monoidal product) joins two types, allowing for multiple types in the inputs and outputs of processes. To the schema, this means nothing more than that, for the process train there are two objects need for the input, the first of type NeuralNet and the second of type Images.

# Add Processes to presentation
extract, split, train,
evaluate = add_processes!(present, [(:extract, File, Images),
                                    (:split, Images, ImagesImages),
                                    (:train, NeuralNetImages, NeuralNetMetadata),
                                    (:evaluate, NeuralNetImages, AccuracyMetadata)]);

Generating the Schema

Once this presentation is defined, the database schema can be generated as follows:

# Convert to Schema
TrainDB = present_to_schema(present);
print(generate_schema_sql(TrainDB()))
CREATE TABLE evaluate (NeuralNet1 text, Images2 text, Accuracy3 real, Metadata4 text);
CREATE TABLE extract (File1 text, Images2 text);
CREATE TABLE split (Images1 text, Images2 text, Images3 text);
CREATE TABLE train (NeuralNet1 text, Images2 text, NeuralNet3 text, Metadata4 text);

Creating Queries

In order to create queries, we use the @query macro (based on the @relation macro in Catlab). For this, we must specify a list of objects to get as results of the query, list of all objects used in the query, and finally a list of relationships between these objects (based on the primitives defined for the workflow). In this case, the relationships between objects are the processes from the presentation and the types of objects are the types defined in the presentation. Following is an example workflow

q = @query TrainDB() (im_train, nn, im_test, acc, md2) where (im_train, im_test, nn,
                                                              nn_trained, acc, md,
                                                              md2, _base_acc, im) begin
    train(nn, im_train, nn_trained, md)
    evaluate(nn_trained, im_test, acc, md2)
    split(im, im_train, im_test)
    >=(acc, _base_acc)
end
print(to_sql(q))

This produces the following query:

SELECT t1.Images2 AS im_train, t1.NeuralNet1 AS nn, t2.Images2 AS im_test, t2.Accuracy3 AS acc, t2.Metadata4 AS md2
FROM train AS t1, evaluate AS t2, split AS t3
WHERE t2.NeuralNet1=t1.NeuralNet3 AND t3.Images2=t1.Images2 AND t3.Images3=t2.Images2 AND t2.Accuracy3>=$1

Connecting to PostgreSQL

The connection to PostgreSQL is fairly straightforward. We first create a connection using the LibPQ.jl library:

conn = Connection("dbname=test_db");

We then can prepare statements and run them with arguments like:

statement = prepare(conn,q)
execute(statement, [0.6])

which will obtain all of the rows from the previous query which contain an accuracy of greater than 0.6.

The execute function will return a DataFrame object (from the DataFrames.jl library)

Theory

Some excellent resources for understanding how Bicategories of Relations relate to SQL queries (and inspiriation for this library) are as follows:

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