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A novel Inductive Logic Programming(ILP) system based on Meta Inverse Entailment in Python.

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PyGol

PyGol is a novel Inductive Logic Programming(ILP) system based on Meta Inverse Entailment(MIE) using Python. MIE is similar to Mode-Directed Inverse Entailment (MDIE) but does not require mode declarations. MIE can be applied to tabular and relational datasets with minimal user intervention or parameter settings. In MIE, each hypothesis clause is derived from a meta theory generated automatically from background knowledge. Meta theory can also be viewed as a higher-order language bias that defines the hypothesis space.

PyGol is a Python library that can be used in Python programs (e.g., Jupyter Notebooks). It can also connect with SWI-Prolog via Janus.

PyGol is free to use for non-commercial research and education. If you use PyGol for research, please cite the paper: Efficient Abductive Learning of Microbial Interactions using Meta Inverse Entailment.

Dany Varghese, Didac Barroso-Bergada, David A. Bohan  and  Alireza Tamaddoni-Nezhad, 
Efficient Abductive Learning of Microbial Interactions using Meta Inverse Entailment,  
In Proceedings of the 31st International Conference on ILP, Springer, 2022.

Anyone wishing to use PyGol for commercial purposes should contact either Dany Varghese(dany.varghese@surrey.ac.uk) or Alireza Tamaddoni-Nezhad(a.tamaddoni-nezhad@surrey.ac.uk).

Contributions

  • An ILP approach Meta Inverse Entailment(MIE)
  • An algorithm to generate Bottom Clause of Relevant Literals (BCRL)
  • A new higher-order language bias Meta Theory (MT) - Automatically generating from BCRL
  • Abductive Learning using MIE
  • Meta Inverse Entailment (MIE) for the purpose of automated data science

Requirements

Using PyGol

PyGol package is provided as a C code. The shared-object file pygol.so runs in Python. The current shared-object file is compiled for Mac M1 systems.

For all other systems, you can find the C code and convert it to shared-object by executing the generate_so.py by following commands;

python3 generate_so.py build_ext --inplace

Example Problem

PyGol requires four inputs, either in the form of files or a list

  1. Background knowledge (BK)
  2. Positive example
  3. Negative example
  4. Constants

The following code demonstrates learning the famous Michalski train problem. Any file extensions can be used for the input files.

Background knowledge - BK.pl

.
.
has_car(west10,car_101).
has_car(west10,car_102).
short(car_101).
long(car_102).
shape(car_101,u_shaped).
shape(car_102,rectangle).
open(car_101).
.
.

Positive Example - pos_example.f

eastbound(east1).
eastbound(east2).
eastbound(east3).
eastbound(east4).
eastbound(east5).

Negative Example - neg_example.n

eastbound(west6).
eastbound(west7).
eastbound(west8).
eastbound(west9).
eastbound(west10).

Constants - Python List

const=["elipse", "hexagon","rectangle","u_shaped","triangle","hexagon","circle","nil"]

Python Execution

# Import package from root folder
import sys
sys.path.insert(0, '../../')
from pygol import *

#Define the constants
const=["elipse", "hexagon","rectangle","u_shaped","triangle","hexagon","circle","nil"]

#Generate the bottom clauses
P, N = bottom_clause_generation(constant_set = const,  container = "memory")

# Split examples into train and test subsets
Train_P, Test_P, Train_N, Test_N=pygol_train_test_split(test_size=0, positive_file_dictionary=P, 
                                                                 negative_file_dictionary=N)

#Learning Phase/Training Phase using Python
model= pygol_learn(Train_P, Train_N,  max_neg=0, max_literals=3, key_size=1)

Output from learning phase

+----------+ Training +----------+
['eastbound(A):-has_car(A,B),closed(B),short(B)']
+---------------------+------------------+------------------+
|       n = 10        | Positive(Actual) | Negative(Actual) |
+=====================+==================+==================+
| Positive(Predicted) | 5                | 0                |
+---------------------+------------------+------------------+
| Negative(Predicted) | 0                | 5                |
+---------------------+------------------+------------------+
+-------------+---+
|   Metric    | # |
+=============+===+
| Accuracy    | 1 |
+-------------+---+
| Precision   | 1 |
+-------------+---+
| Sensitivity | 1 |
+-------------+---+
| Specificity | 1 |
+-------------+---+
| F1 Score    | 1 |
+-------------+---+

Recursion

PyGol is capable of learning recursive programs where a predicate symbol is present in both the rule's head and its body.

To lean recursive rule, recursive and rule_noise_check variable should be set as True inside pygol_learn().

model= pygol_learn(_ ,_ , ... , rule_noise_check = True, recursive = True)

Please refer to ancestor relation learning problem.

Predicate invention

PyGol can also perform automatic predicate invention and for that pi varibale should set as True.

model= pygol_learn(_ ,_ , ... ,  pi = True)

Please refer to grandparent relation learning problem.

Learning settings

  • ILP Learning Approach :- pygol_learn()
  • ILP Cross-Validation Approach :- pygol_cross_validation()
  • ILP abduction (Reasoning) :- pygol_abduction()

For further information, please find the manual.

Publications

Packages

  • InfIntE: InfIntE stands for Inference of Interactions using Explainable machine learning. This package uses abundance data to directly infer ecological interactions using PyGol, an Abductive/Inductive logic program, classified by their interaction type.

Bug reports and feature requests

Please submit all bug reports and feature requests as issues on this GitHub repository.