zoofs 0.1.26

zoofs is a Python library for performing feature selection using an variety of nature inspired wrapper algorithms..

🐾 zoofs ( Zoo Feature Selection )

zoofs is a Python library for performing feature selection using a variety of nature inspired wrapper algorithms. The algorithms range from swarm-intelligence to physics based to Evolutionary. It's an easy to use, flexible and powerful tool to reduce your feature size.

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📘 Documentation

https://jaswinder9051998.github.io/zoofs/

🔗 Whats new in V0.1.24

• pass kwargs through objective function
• improved logger for results
• added harris hawk algorithm
• now you can pass timeout as a parameter to stop operation after the given number of second(s). An amazing alternative to passing number of iterations
• Feature score hashing of visited feature sets to increase the overall performance

🛠 Installation

Using pip

Use the package manager to install zoofs.

pip install zoofs

📜 Available Algorithms

Algorithm Name	Class Name	Description	References doi
Particle Swarm Algorithm	ParticleSwarmOptimization	Utilizes swarm behaviour	https://doi.org/10.1007/978-3-319-13563-2_51
Grey Wolf Algorithm	GreyWolfOptimization	Utilizes wolf hunting behaviour	https://doi.org/10.1016/j.neucom.2015.06.083
Dragon Fly Algorithm	DragonFlyOptimization	Utilizes dragonfly swarm behaviour	https://doi.org/10.1016/j.knosys.2020.106131
Harris Hawk Algorithm	HarrisHawkOptimization	Utilizes hawk hunting behaviour	https://link.springer.com/chapter/10.1007/978-981-32-9990-0_12
Genetic Algorithm Algorithm	GeneticOptimization	Utilizes genetic mutation behaviour	https://doi.org/10.1109/ICDAR.2001.953980
Gravitational Algorithm	GravitationalOptimization	Utilizes newtons gravitational behaviour	https://doi.org/10.1109/ICASSP.2011.5946916

More algos soon, stay tuned !

• [Try It Now?]

⚡️ Usage

Define your own objective function for optimization !

Classification Example

from sklearn.metrics import log_loss
# define your own objective function, make sure the function receives four parameters,
#  fit your model and return the objective value !
def objective_function_topass(model,X_train, y_train, X_valid, y_valid):      
    model.fit(X_train,y_train)  
    P=log_loss(y_valid,model.predict_proba(X_valid))
    return P

# import an algorithm !  
from zoofs import ParticleSwarmOptimization
# create object of algorithm
algo_object=ParticleSwarmOptimization(objective_function_topass,n_iteration=20,
                                       population_size=20,minimize=True)
import lightgbm as lgb
lgb_model = lgb.LGBMClassifier()                                       
# fit the algorithm
algo_object.fit(lgb_model,X_train, y_train, X_valid, y_valid,verbose=True)
#plot your results
algo_object.plot_history()

Regression Example

from sklearn.metrics import mean_squared_error
# define your own objective function, make sure the function receives four parameters,
#  fit your model and return the objective value !
def objective_function_topass(model,X_train, y_train, X_valid, y_valid):      
    model.fit(X_train,y_train)  
    P=mean_squared_error(y_valid,model.predict(X_valid))
    return P

# import an algorithm !  
from zoofs import ParticleSwarmOptimization
# create object of algorithm
algo_object=ParticleSwarmOptimization(objective_function_topass,n_iteration=20,
                                       population_size=20,minimize=True)
import lightgbm as lgb
lgb_model = lgb.LGBMRegressor()                                       
# fit the algorithm
algo_object.fit(lgb_model,X_train, y_train, X_valid, y_valid,verbose=True)
#plot your results
algo_object.plot_history()

Suggestions for Usage

• As available algorithms are wrapper algos, it is better to use ml models that build quicker, e.g lightgbm, catboost.
• Take sufficient amount for 'population_size' , as this will determine the extent of exploration and exploitation of the algo.
• Ensure that your ml model has its hyperparamters optimized before passing it to zoofs algos.

objective score plot

Algorithms

Particle Swarm Algorithm

In computational science, particle swarm optimization (PSO) is a computational method that optimizes a problem by iteratively trying to improve a candidate solution with regard to a given measure of quality. It solves a problem by having a population of candidate solutions, here dubbed particles, and moving these particles around in the search-space according to simple mathematical formula over the particle's position and velocity. Each particle's movement is influenced by its local best known position, but is also guided toward the best known positions in the search-space, which are updated as better positions are found by other particles. This is expected to move the swarm toward the best solutions.

---

class zoofs.ParticleSwarmOptimization(objective_function,n_iteration=50,population_size=50,minimize=True,c1=2,c2=2,w=0.9)

---

Parameters	objective_function : user made function of the signature 'func(model,X_train,y_train,X_test,y_test)'. The function must return a value, that needs to be minimized/maximized. n_iteration : int, default=1000 Number of time the algorithm will run timeout: int = None Stop operation after the given number of second(s). If this argument is set to None, the operation is executed without time limitation and n_iteration is followed population_size : int, default=50 Total size of the population minimize : bool, default=True Defines if the objective value is to be maximized or minimized c1 : float, default=2.0 first acceleration coefficient of particle swarm c2 : float, default=2.0 second acceleration coefficient of particle swarm w : float, default=0.9 weight parameter
Attributes	best_feature_list : array-like Final best set of features

Methods

Methods	Class Name
fit	Run the algorithm
plot_history	Plot results achieved across iteration

fit(model,X_train, y_train, X_test, y_test,verbose=True)

Parameters	model : machine learning model's object X_train : pandas.core.frame.DataFrame of shape (n_samples, n_features) Training input samples to be used for machine learning model y_train : pandas.core.frame.DataFrame or pandas.core.series.Series of shape (n_samples) The target values (class labels in classification, real numbers in regression). X_valid : pandas.core.frame.DataFrame of shape (n_samples, n_features) Validation input samples y_valid : pandas.core.frame.DataFrame or pandas.core.series.Series of shape (n_samples) The Validation target values . verbose : bool,default=True Print results for iterations
Returns	best_feature_list : array-like Final best set of features

plot_history()

Plot results across iterations

Example

from sklearn.metrics import log_loss
# define your own objective function, make sure the function receives four parameters,
#  fit your model and return the objective value !
def objective_function_topass(model,X_train, y_train, X_valid, y_valid):      
    model.fit(X_train,y_train)  
    P=log_loss(y_valid,model.predict_proba(X_valid))
    return P

# import an algorithm !  
from zoofs import ParticleSwarmOptimization
# create object of algorithm
algo_object=ParticleSwarmOptimization(objective_function_topass,n_iteration=20,
                                       population_size=20,minimize=True,c1=2,c2=2,w=0.9)
import lightgbm as lgb
lgb_model = lgb.LGBMClassifier()                      
# fit the algorithm
algo_object.fit(lgb_model,X_train, y_train, X_valid, y_valid,verbose=True)
#plot your results
algo_object.plot_history()

Grey Wolf Algorithm

The Grey Wolf Optimizer (GWO) mimics the leadership hierarchy and hunting mechanism of grey wolves in nature. Four types of grey wolves such as alpha, beta, delta, and omega are employed for simulating the leadership hierarchy. In addition, three main steps of hunting, searching for prey, encircling prey, and attacking prey, are implemented to perform optimization.

---

class zoofs.GreyWolfOptimization(objective_function,n_iteration=50,population_size=50,minimize=True)

---

Parameters	objective_function : user made function of the signature 'func(model,X_train,y_train,X_test,y_test)'. The function must return a value, that needs to be minimized/maximized. n_iteration : int, default=50 Number of time the algorithm will run timeout: int = None Stop operation after the given number of second(s). If this argument is set to None, the operation is executed without time limitation and n_iteration is followed population_size : int, default=50 Total size of the population method : {1, 2}, default=1 Choose the between the two methods of grey wolf optimization minimize : bool, default=True Defines if the objective value is to be maximized or minimized
Attributes	best_feature_list : array-like Final best set of features

Methods

Methods	Class Name
fit	Run the algorithm
plot_history	Plot results achieved across iteration

fit(model,X_train,y_train,X_valid,y_valid,method=1,verbose=True)

Parameters	model : machine learning model's object X_train : pandas.core.frame.DataFrame of shape (n_samples, n_features) Training input samples to be used for machine learning model y_train : pandas.core.frame.DataFrame or pandas.core.series.Series of shape (n_samples) The target values (class labels in classification, real numbers in regression). X_valid : pandas.core.frame.DataFrame of shape (n_samples, n_features) Validation input samples y_valid : pandas.core.frame.DataFrame or pandas.core.series.Series of shape (n_samples) The Validation target values . verbose : bool,default=True Print results for iterations
Returns	best_feature_list : array-like Final best set of features

plot_history()

Plot results across iterations

Example

from sklearn.metrics import log_loss
# define your own objective function, make sure the function receives four parameters,
#  fit your model and return the objective value !
def objective_function_topass(model,X_train, y_train, X_valid, y_valid):      
    model.fit(X_train,y_train)  
    P=log_loss(y_valid,model.predict_proba(X_valid))
    return P

# import an algorithm !  
from zoofs import GreyWolfOptimization
# create object of algorithm
algo_object=GreyWolfOptimization(objective_function_topass,n_iteration=20,method=1,
                                    population_size=20,minimize=True)
import lightgbm as lgb
lgb_model = lgb.LGBMClassifier()                                       
# fit the algorithm
algo_object.fit(lgb_model,X_train, y_train, X_valid, y_valid,verbose=True)
#plot your results
algo_object.plot_history()

Dragon Fly Algorithm

The main inspiration of the Dragonfly Algorithm (DA) algorithm originates from static and dynamic swarming behaviours. These two swarming behaviours are very similar to the two main phases of optimization using meta-heuristics: exploration and exploitation. Dragonflies create sub swarms and fly over different areas in a static swarm, which is the main objective of the exploration phase. In the static swarm, however, dragonflies fly in bigger swarms and along one direction, which is favourable in the exploitation phase.

---

class zoofs.DragonFlyOptimization(objective_function,n_iteration=50,population_size=50,minimize=True)

---

Parameters	objective_function : user made function of the signature 'func(model,X_train,y_train,X_test,y_test)'. The function must return a value, that needs to be minimized/maximized. n_iteration : int, default=50 Number of time the algorithm will run timeout: int = None Stop operation after the given number of second(s). If this argument is set to None, the operation is executed without time limitation and n_iteration is followed population_size : int, default=50 Total size of the population method : {'linear','random','quadraic','sinusoidal'}, default='sinusoidal' Choose the between the three methods of Dragon Fly optimization minimize : bool, default=True Defines if the objective value is to be maximized or minimized
Attributes	best_feature_list : array-like Final best set of features

Methods

Methods	Class Name
fit	Run the algorithm
plot_history	Plot results achieved across iteration

fit(model,X_train,y_train,X_valid,y_valid,method='sinusoidal',verbose=True)

Parameters	model : machine learning model's object X_train : pandas.core.frame.DataFrame of shape (n_samples, n_features) Training input samples to be used for machine learning model y_train : pandas.core.frame.DataFrame or pandas.core.series.Series of shape (n_samples) The target values (class labels in classification, real numbers in regression). X_valid : pandas.core.frame.DataFrame of shape (n_samples, n_features) Validation input samples y_valid : pandas.core.frame.DataFrame or pandas.core.series.Series of shape (n_samples) The Validation target values . verbose : bool,default=True Print results for iterations
Returns	best_feature_list : array-like Final best set of features

plot_history()

Plot results across iterations

Example

from sklearn.metrics import log_loss
# define your own objective function, make sure the function receives four parameters,
#  fit your model and return the objective value !
def objective_function_topass(model,X_train, y_train, X_valid, y_valid):      
    model.fit(X_train,y_train)  
    P=log_loss(y_valid,model.predict_proba(X_valid))
    return P

# import an algorithm !  
from zoofs import DragonFlyOptimization
# create object of algorithm
algo_object=DragonFlyOptimization(objective_function_topass,n_iteration=20,method='sinusoidal',
                                    population_size=20,minimize=True)
import lightgbm as lgb
lgb_model = lgb.LGBMClassifier()                                     
# fit the algorithm
algo_object.fit(lgb_model,X_train, y_train, X_valid, y_valid,  verbose=True)
#plot your results
algo_object.plot_history()

Harris Hawk Optimization

HHO is a popular swarm-based, gradient-free optimization algorithm with several active and time-varying phases of exploration and exploitation. This algorithm initially published by the prestigious Journal of Future Generation Computer Systems (FGCS) in 2019, and from the first day, it has gained increasing attention among researchers due to its flexible structure, high performance, and high-quality results. The main logic of the HHO method is designed based on the cooperative behaviour and chasing styles of Harris' hawks in nature called "surprise pounce". Currently, there are many suggestions about how to enhance the functionality of HHO, and there are also several enhanced variants of the HHO in the leading Elsevier and IEEE transaction journals.

---

class zoofs.HarrisHawkOptimization(objective_function,n_iteration=50,population_size=50,minimize=True,beta=0.5)

---

Parameters	objective_function : user made function of the signature 'func(model,X_train,y_train,X_test,y_test)'. The function must return a value, that needs to be minimized/maximized. n_iteration : int, default=1000 Number of time the algorithm will run timeout: int = None Stop operation after the given number of second(s). If this argument is set to None, the operation is executed without time limitation and n_iteration is followed population_size : int, default=50 Total size of the population minimize : bool, default=True Defines if the objective value is to be maximized or minimized beta : float, default=0.5 value for levy random walk
Attributes	best_feature_list : array-like Final best set of features

Methods

Methods	Class Name
fit	Run the algorithm
plot_history	Plot results achieved across iteration

fit(model,X_train, y_train, X_test, y_test,verbose=True)

Parameters	model : machine learning model's object X_train : pandas.core.frame.DataFrame of shape (n_samples, n_features) Training input samples to be used for machine learning model y_train : pandas.core.frame.DataFrame or pandas.core.series.Series of shape (n_samples) The target values (class labels in classification, real numbers in regression). X_valid : pandas.core.frame.DataFrame of shape (n_samples, n_features) Validation input samples y_valid : pandas.core.frame.DataFrame or pandas.core.series.Series of shape (n_samples) The Validation target values . verbose : bool,default=True Print results for iterations
Returns	best_feature_list : array-like Final best set of features

plot_history()

Plot results across iterations

Example

from sklearn.metrics import log_loss
# define your own objective function, make sure the function receives four parameters,
#  fit your model and return the objective value !
def objective_function_topass(model,X_train, y_train, X_valid, y_valid):      
    model.fit(X_train,y_train)  
    P=log_loss(y_valid,model.predict_proba(X_valid))
    return P

# import an algorithm !  
from zoofs import HarrisHawkOptimization
# create object of algorithm
algo_object=HarrisHawkOptimization(objective_function_topass,n_iteration=20,
                                       population_size=20,minimize=True)
import lightgbm as lgb
lgb_model = lgb.LGBMClassifier()                      
# fit the algorithm
algo_object.fit(lgb_model,X_train, y_train, X_valid, y_valid,verbose=True)
#plot your results
algo_object.plot_history()

Genetic Algorithm

In computer science and operations research, a genetic algorithm (GA) is a metaheuristic inspired by the process of natural selection that belongs to the larger class of evolutionary algorithms (EA). Genetic algorithms are commonly used to generate high-quality solutions to optimization and search problems by relying on biologically inspired operators such as mutation, crossover and selection. Some examples of GA applications include optimizing decision trees for better performance, automatically solve sudoku puzzles, hyperparameter optimization, etc.

---

class zoofs.GeneticOptimization(objective_function,n_iteration=20,population_size=20,selective_pressure=2,elitism=2,mutation_rate=0.05,minimize=True)

---

Parameters	objective_function : user made function of the signature 'func(model,X_train,y_train,X_test,y_test)'. The function must return a value, that needs to be minimized/maximized. n_iteration: int, default=50 Number of time the algorithm will run timeout: int = None Stop operation after the given number of second(s). If this argument is set to None, the operation is executed without time limitation and n_iteration is followed population_size : int, default=50 Total size of the population selective_pressure: int, default=2 measure of reproductive opportunities for each organism in the population elitism: int, default=2 number of top individuals to be considered as elites mutation_rate: float, default=0.05 rate of mutation in the population's gene minimize: bool, default=True Defines if the objective value is to be maximized or minimized
Attributes	best_feature_list : array-like Final best set of features

Methods

Methods	Class Name
fit	Run the algorithm
plot_history	Plot results achieved across iteration

fit(model,X_train,y_train,X_valid,y_valid,verbose=True)

Parameters	model : machine learning model's object X_train : pandas.core.frame.DataFrame of shape (n_samples, n_features) Training input samples to be used for machine learning model y_train : pandas.core.frame.DataFrame or pandas.core.series.Series of shape (n_samples) The target values (class labels in classification, real numbers in regression). X_valid : pandas.core.frame.DataFrame of shape (n_samples, n_features) Validation input samples y_valid : pandas.core.frame.DataFrame or pandas.core.series.Series of shape (n_samples) The Validation target values . verbose : bool,default=True Print results for iterations
Returns	best_feature_list : array-like Final best set of features

plot_history()

Plot results across iterations

Example

from sklearn.metrics import log_loss
# define your own objective function, make sure the function receives four parameters,
#  fit your model and return the objective value !
def objective_function_topass(model,X_train, y_train, X_valid, y_valid):      
    model.fit(X_train,y_train)  
    P=log_loss(y_valid,model.predict_proba(X_valid))
    return P

# import an algorithm !  
from zoofs import GeneticOptimization
# create object of algorithm
algo_object=GeneticOptimization(objective_function_topass,n_iteration=20,
                            population_size=20,selective_pressure=2,elitism=2,
                            mutation_rate=0.05,minimize=True)
import lightgbm as lgb
lgb_model = lgb.LGBMClassifier()                            
# fit the algorithm
algo_object.fit(lgb_model,X_train, y_train,X_valid, y_valid, verbose=True)
#plot your results
algo_object.plot_history()

Gravitational Algorithm

Gravitational Algorithm is based on the law of gravity and mass interactions is introduced. In the algorithm, the searcher agents are a collection of masses which interact with each other based on the Newtonian gravity and the laws of motion.

---

class zoofs.GravitationalOptimization(self,objective_function,n_iteration=50,population_size=50,g0=100,eps=0.5,minimize=True)

---

Parameters	objective_function : user made function of the signature 'func(model,X_train,y_train,X_test,y_test)'. The function must return a value, that needs to be minimized/maximized. n_iteration: int, default=50 Number of time the algorithm will run timeout: int = None Stop operation after the given number of second(s). If this argument is set to None, the operation is executed without time limitation and n_iteration is followed population_size : int, default=50 Total size of the population g0: float, default=100 gravitational strength constant eps: float, default=0.5 distance constant minimize: bool, default=True Defines if the objective value is to be maximized or minimized
Attributes	best_feature_list : array-like Final best set of features

Methods

Methods	Class Name
fit	Run the algorithm
plot_history	Plot results achieved across iteration

fit(model,X_train,y_train,X_valid,y_valid,verbose=True)

Parameters	model : machine learning model's object X_train : pandas.core.frame.DataFrame of shape (n_samples, n_features) Training input samples to be used for machine learning model y_train : pandas.core.frame.DataFrame or pandas.core.series.Series of shape (n_samples) The target values (class labels in classification, real numbers in regression). X_valid : pandas.core.frame.DataFrame of shape (n_samples, n_features) Validation input samples y_valid : pandas.core.frame.DataFrame or pandas.core.series.Series of shape (n_samples) The Validation target values . verbose : bool,default=True Print results for iterations
Returns	best_feature_list : array-like Final best set of features

plot_history()

Plot results across iterations

Example

from sklearn.metrics import log_loss
# define your own objective function, make sure the function receives four parameters,
#  fit your model and return the objective value !
def objective_function_topass(model,X_train, y_train, X_valid, y_valid):      
    model.fit(X_train,y_train)  
    P=log_loss(y_valid,model.predict_proba(X_valid))
    return P

# import an algorithm !  
from zoofs import GravitationalOptimization
# create object of algorithm
algo_object=GravitationalOptimization(objective_function_topass,n_iteration=50,
                                population_size=50,g0=100,eps=0.5,minimize=True)
import lightgbm as lgb
lgb_model = lgb.LGBMClassifier()                                
# fit the algorithm
algo_object.fit(lgb_model,X_train, y_train, X_valid, y_valid, verbose=True)
#plot your results
algo_object.plot_history()

Support zoofs

The development of zoofs relies completely on contributions.

Contributing

Pull requests are welcome. For major changes, please open an issue first to discuss what you would like to change.

Please make sure to update tests as appropriate.

First roll out

18,08,2021

License

apache-2.0