Metadata-Version: 2.1
Name: hivae
Version: 0.1
Summary: HIVAE (https://arxiv.org/pdf/1807.03653.pdf - by Nazabal, Olmos, Ghahramani, Valera) - extenstion of their implementations as Python library
Home-page: https://github.com/gkoutos-group/hivae/
Author: Andreas Karwath
Author-email: a.karwath@bham.ac.uk
License: MIT
Platform: UNKNOWN
Description-Content-Type: text/markdown
Requires-Dist: tensorflow (>=1.13.0)
Requires-Dist: pandas
Requires-Dist: sklearn

# hivae

This repository contains the Modular reimplemenation of the Heterogeneous Incomplete Variational Autoencoder model (HI-VAE)written by Alfredo Nazabal (anazabal@turing.ac.uk). It was written in Python, using Tensorflow.

The details of this model are included in this [paper](https://arxiv.org/abs/1807.03653). Please cite it if you use this code/library for your own research.

## Database description

There are three different example datasets found in the library (Wine, Adult and Diabetes). Majority of the datasets( Wine and Adult) have each their own folder, containing:

* **data.csv**: the dataset
* **data_types.csv(NOT REQUIRED, LOOK AT THE EXAMPLE(working_example)**: a csv containing the types of that particular dataset. Every line is a different attribute containing three paramenters:
	* type: real, pos (positive), cat (categorical), ord (ordinal), count
	* dim: dimension of the variable
	* nclass: number of categories (for cat and ord)
* **Missingxx_y.csv**: a csv containing the positions of the different missing values in the data. Each "y" mask was generated randomly, containing a "xx" % of missing values.

You can add your own datasets as long as they follow this structure.


## Files description

* **HIVAE.py**: The main script of the library, it needs to imported to work with the library and is connected to all the other scripts.
* **loglik_ models_ missing_normalize.py**: In this file, the different likelihood models for the different types of variables considered (real, positive, count, categorical and ordinal) are included.
* **model_ HIVAE_inputDropout.py**: Contains the HI-VAE with input dropout encoder model.
* **model_ HIVAE_factorized.py**: Contains the HI-VAE with factorized encoder model

## Contact

* **For questions regarding algorithm --> Alfredo Nazabal**: anazabal@turing.ac.uk
* **For bugs or suggestion regarding code --> Fathy Shalaby**: fathy.mshalaby@outlook.com

## Comments on general_example.py


main_directory: where is the project folder

dataset_name: the name of the database (if you want)

types_list_d: a dictionary where the key is the dataset name, which contains a list with tuples that indicates the column names, types, the number of dimensions and classes 

types:

•	count: real values

•	cat: categorical 0 or 1

•	pos: positive real values

•	ordinal: ordinal number

number of dimensions:

•	number of possibilities in the categorical variables or 1 in numerical

number of classes:

•	number of options (same of number of dimensions for categorical variables)

dataset_path: this is the folder of the csv files

results_path: the output folder for results

network_path: where the models are going to be stored

types_list: the specific type for the dataset you are going to use
data_file: the full dataset
train_file/ test_file: if the dataset was already splitted

train_data/test_data: pandas dataframes

dim_y: the depth of the network

dim_s/dim_z: dimensions of the embedding


