This repo is archived and the development continues on https://pasaopasen.github.io/geneticalgorithm2/
geneticalgorithm2 (from DPEA) is the supported advanced optimized fork of non-supported package geneticalgorithm of Ryan (Mohammad) Solgi
- About
- Installation
- Updates information
- Future
- TODO firstly
- 6.8.7 minor update
- 6.8.6 minor update
- 6.8.5 minor update
- 6.8.4 minor update
- 6.8.3 types update
- 6.8.2 patch
- 6.8.1 patch
- 6.8.0 minor update
- 6.7.7 refactor
- 6.7.6 bug fix
- 6.7.5 refactor
- 6.7.4 bug fix
- 6.7.3 speed up
- 6.7.2 little update
- 6.7.1 patch
- 6.7.0 minor update (new features)
- 6.6.2 patch (speed up)
- 6.6.1 patch
- 6.6.0 minor update (refactoring)
- 6.5.1 patch
- 6.5.0 minor update (refactoring)
- 6.4.1 patch (bug fix)
- 6.4.0 minor update (refactoring)
- 6.3.0 minor update (refactoring)
- Working process
- Examples for beginner
- U should know these features
- Available crossovers
- Function timeout
- Standard GA vs. Elitist GA
- Standard crossover vs. stud EA crossover
- Creating better start population
- Revolutions
- Duplicates removing
- Cache
- Report checker
- Middle callbacks
- How to compare efficiency of several versions of GA optimization
- Hints on how to adjust genetic algorithm's parameters (from
geneticalgorithm
package) - How to get maximum speed
- Examples pretty collection
- Popular questions
geneticalgorithm2 is very flexible and highly optimized Python library for implementing classic genetic-algorithm (GA).
Features of this package:
- written on pure python
- extremely fast
- no hard dependencies (only numpy primary, can work without matplotlib)
- easy to run: no need to perform long task-setup process
- easy to logging, reach support of flexible callbacks
- many built-in plotting functions
- many built-in cases of crossover, mutation and selection
- support of integer, boolean and real (continuous/discrete) variables types
- support of mixed types of variables
- support of classic, elitist and studEA genetic algorithm combinations
- support of revolutions and duplicates utilization
- reach support of customization
Install this package with standard dependencies to use the entire functional.
pip install geneticalgorithm2
Install this package with full dependencies to use all provided functional.
pip install geneticalgorithm2[full]
- duplicates removing and revolutions will be moved to
MiddleCallbacks
and removed as alonerun()
parameters function_timeout
andfunction
will be moved torun()
method- new stop criteria callbacks (min std, max functions evaluations)
vartype
will support strings likeiiiiibbf
- Remove old style mensions from README
- some code refactor
- fixes:
- ensure the directory of generation file exists on save
- small package installation update: add
pip install geneticalgorithm2[full]
version - small refactor
- update
OppOpPopInit
2.0.0->2.0.1
- set default
function_timeout
toNone
which means no use of function time checking - remove
joblib
andfunc_timeout
from necessary dependencies
- a bit of refactor
- little optimizations
- add empty field
fill_children(pop_matrix, parents_count)
togeneticalgorithm2
class to specify children creating behavior (what is the most intensive part of algorithm after optimizing func calculations), see this
- much more type hints
- for printing info
- fix logic: now population is always sorted before going to callbacks
- printing progress bar to
'stderr'
or'stdout'
orNone
(disable) by choice (progress_bar_stream
argument ofrun()
), deprecateddisable_progress_bar
- little speed up
- new
geneticalgorithm2.vectorized_set_function
set function, which can be faster for big populations
- remove
crossover_probability
model parameter because of it has no sense to exist (and 1.0 value is better than others, take a look at results). This parameter came fromgeneticalgorithm
old package and did`t change before.
- change some behavior about parents selection
- fix some bug of
variable_type=='bool'
- some refactor of progress bar
- add some dependencies to
setup.py
- shorter progress bar (length can be controlled by setting
PROGRESS_BAR_LEN
field ofgeneticalgorithm2
class) - shorter logic of
run()
, more informative output
- bug fix
- refactor to make
run()
method faster
- better flexible logic for report, take a look
- removed
show mean
parameter frommodel.plot_result
and now model reports only best score by default, not average and so on (u can specify if u wanna report average too) plot_several_lines
useful function
- changes according to new OppOpPopInit version
- add
mutation_discrete_type
andmutation_discrete_probability
parameters in model. It controls mutation behavior for discrete (integer) variables and works likemutation_type
andmutation_probability
work for continuous (real) variables. Take a look at algorithm parameters
- fix and speed up mutation
- removed unnecessary dependencies
- deprecated
variable_type_mixed
, now usevariable_type
for mixed optimization too - deprecated
output_dict
, now it's better object with nameresult
- refactor of big part of tests
- refactor of README
- replace
collections.Sequence
withcollections.abc.Sequence
, now it should work forpython3.10+
- another form of data object using with middle callbacks (
MiddleCallbackData
dataclass instead of dictionary) - type hints for callbacks module
- fix bug setting attribute to algorithm parameters (in middle callbacks)
-
new valid forms for
start_generation
; now it's valid to useNone
str
path to saved generation- dictionary with structure
{'variables': variables/None, 'scores': scores/None}
Generation
object:Generation(variables = variables, scores = scores)
np.ndarray
with shape(samples, dim)
for only population or(samples, dim+1)
for concatenated population and score (scores is the last matrix column)tuple(np.ndarray/None, np.ndarray/None)
for variables and scores
here
variables
is 2D numpy array with shape(samples, dim)
,scores
is 1D numpy array with scores (function values) for each sample; here and here u can see examples of using these valid forms
- type hints for entire part of functions
- new valid forms for function parameters (now u don't need to use numpy arrays everywhere)
AlgorithmParams
class for base GA algorithm parameters (instead of dictionary)Generation
class for saving/loading/returning generation (instead of dictionary)
All that classes are collected in file. To maintain backward compatibility, AlgorithmParams
and Generation
classes have dictionary-like interface for getting fields: u can use object.field
or object['field']
notations.
Pre-process: making inner functions depends on params, making/loading start population
while True:
if reason to stop (time is elapsed / no progress / generation count is reached / min value is reached):
break
select parents to crossover from last population and put them to new population:
select (elit count) best samples
select (parents count - elit count) random samples (by selection function)
create (total samples count - parents count) children (samples from selected parents) and put them to new population:
while not all children are created:
select 2 random parents
make child1, child2 from them using crossover
mutate child1 by mutation (model.mut)
mutate child2 by middle mutation (model.mut_middle)
put children to new population
remove duplicates, make revolutions, sort population by scores
use callbacks, use middle callbacks
Post-process: plotting results, saving
Firstly, u should import needed packages. All available (but not always necessary) imports are:
import numpy as np
# the only one required import
from geneticalgorithm2 import geneticalgorithm2 as ga # for creating and running optimization model
from geneticalgorithm2 import Generation, AlgorithmParams # classes for comfortable parameters setting and getting
from geneticalgorithm2 import Crossover, Mutations, Selection # classes for specific mutation and crossover behavior
from geneticalgorithm2 import Population_initializer # for creating better start population
from geneticalgorithm2 import np_lru_cache # for cache function (if u want)
from geneticalgorithm2 import plot_pop_scores # for plotting population scores, if u want
from geneticalgorithm2 import Callbacks # simple callbacks (will be deprecated)
from geneticalgorithm2 import Actions, ActionConditions, MiddleCallbacks # middle callbacks
Next step: define minimized function like
def function(X: np.ndarray) -> float: # X as 1d-numpy array
return np.sum(X**2) + X.mean() + X.min() + X[0]*X[2] # some float result
If u want to find maximum, use this idea:
f_tmp = lambda arr: -target(arr)
#
# ... find global min
#
target_result = -global_min
Okay, also u should create the bounds for each variable (if exist) like here:
var_bound = np.array([[0,10]]*3) # 2D numpy array with shape (dim, 2)
# also u can use Sequence of Tuples (from version 6.3.0)
var_bound = [
(0, 10),
(0, 10),
(0, 10)
]
U don't need to use variable boundaries only if variable type of each variable is boolean. This case will be converted to discret variables with bounds (0, 1)
.
After that create a geneticalgorithm2
(was imported early as ga) object:
# style before 6.3.0 version (but still works)
model = ga(
function,
dimension = 3,
variable_type='real',
variable_boundaries = var_bound,
function_timeout = 10,
algorithm_parameters={
'max_num_iteration': None,
'population_size':100,
'mutation_probability': 0.1,
'mutation_discrete_probability': None,
'elit_ratio': 0.01,
'parents_portion': 0.3,
'crossover_type':'uniform',
'mutation_type': 'uniform_by_center',
'mutation_discrete_type': 'uniform_discrete',
'selection_type': 'roulette',
'max_iteration_without_improv':None
}
)
# from version 6.3.0 it is equal to
model = ga(
function,
dimension = 3,
variable_type='real',
variable_boundaries = var_bound,
function_timeout = 10,
algorithm_parameters=AlgorithmParams(
max_num_iteration = None,
population_size = 100,
mutation_probability = 0.1,
mutation_discrete_probability = None,
elit_ratio = 0.01,
parents_portion = 0.3,
crossover_type = 'uniform',
mutation_type = 'uniform_by_center',
mutation_discrete_type = 'uniform_discrete',
selection_type = 'roulette',
max_iteration_without_improv = None
)
)
# or (with defaults)
model = ga(
function, dimension = 3,
variable_type='real',
variable_boundaries = var_bound,
function_timeout = 10,
algorithm_parameters=AlgorithmParams()
)
Run the search method:
# all of this parameters are default
result = model.run(
no_plot = False,
progress_bar_stream = 'stdout',
disable_printing = False,
set_function = None,
apply_function_to_parents = False,
start_generation = None,
studEA = False,
mutation_indexes = None,
init_creator = None,
init_oppositors = None,
duplicates_oppositor = None,
remove_duplicates_generation_step = None,
revolution_oppositor = None,
revolution_after_stagnation_step = None,
revolution_part = 0.3,
population_initializer = Population_initializer(select_best_of = 1, local_optimization_step = 'never', local_optimizer = None),
stop_when_reached = None,
callbacks = [],
middle_callbacks = [],
time_limit_secs = None,
save_last_generation_as = None,
seed = None
)
# best solution
print(result.variable)
# best score
print(result.score)
# last generation
print(result.last_generation)
-
function (
Callable[[np.ndarray], float]
) - the given objective function to be minimized
NOTE: This implementation minimizes the given objective function. (For maximization multiply function by a negative sign: the absolute value of the output would be the actual objective function) -
dimension (
int
) - the number of decision variables -
variable_type (
Union[str, Sequence[str]]
) - 'bool' if all variables are Boolean; 'int' if all variables are integer; and 'real' if all variables are real value or continuous. For mixed types use sequence of string of type for each variable -
variable_boundaries (
Optional[Union[np.ndarray, Sequence[Tuple[float, float]]]]
) - Default None; leave it None if variable_type is 'bool'; otherwise provide an sequence of tuples of length two as boundaries for each variable; the length of the array must be equal dimension. For example,np.array([[0,100],[0,200]])
or[(0, 100), (0, 200)]
determines lower boundary 0 and upper boundary 100 for first and upper boundary 200 for second variable where dimension is 2. -
function_timeout (
float
) - if the given function does not provide output before function_timeout (unit is seconds) the algorithm raise error. For example, when there is an infinite loop in the given function.None
means disabling -
algorithm_parameters (
Union[AlgorithmParams, Dict[str, Any]]
). Dictionary or AlgorithmParams object with fields:- @ max_num_iteration (
int/None
) - stopping criteria of the genetic algorithm (GA) - @ population_size (
int > 0
) - @ mutation_probability (
float in [0,1]
) - @ mutation_discrete_probability (
float in [0,1]
orNone
) - @ elit_ration (
float in [0,1]
) - part of elit objects in population; if > 0, there always will be 1 elit object at least - @ parents_portion (
float in [0,1]
) - part of parents from previous population to save in next population (includingelit_ration
) - @ crossover_type (
Union[str, Callable[[np.ndarray, np.ndarray], Tuple[np.ndarray, np.ndarray]]]
) - Default isuniform
. - @ mutation_type (
Union[str, Callable[[float, float, float], float]]
) - Default isuniform_by_center
- @ mutation_discrete_type (
Union[str, Callable[[int, int, int], int]]
) - Default isuniform_discrete
- @ selection_type (
Union[str, Callable[[np.ndarray, int], np.ndarray]]
) - Default isroulette
- @ max_iteration_without_improv (
int/None
) - maximum number of successive iterations without improvement. IfNone
it is ineffective
- @ max_num_iteration (
The parameters of GA is defined as a dictionary or AlgorithmParams
object:
algorithm_param = AlgorithmParams(
max_num_iteration = None,
population_size = 100,
mutation_probability = 0.1,
mutation_discrete_probability = None,
elit_ratio = 0.01,
parents_portion = 0.3,
crossover_type = 'uniform',
mutation_type = 'uniform_by_center',
mutation_discrete_type = 'uniform_discrete',
selection_type = 'roulette',
max_iteration_without_improv = None
)
# old style with dictionary
# sometimes it's easier to use this style
# especially if u need to set only few params
algorithm_param = {
'max_num_iteration': None,
'population_size':100,
'mutation_probability': 0.1,
'mutation_discrete_probability': None,
'elit_ratio': 0.01,
'parents_portion': 0.3,
'crossover_type':'uniform',
'mutation_type': 'uniform_by_center',
'mutation_discrete_type': 'uniform_discrete',
'selection_type': 'roulette',
'max_iteration_without_improv':None
}
To get actual default params use code:
params = ga.default_params
To get actual parameters of existing model use code:
params = model.param
An example of setting a new set of parameters for genetic algorithm and running geneticalgorithm2
for our first simple example again:
import numpy as np
from geneticalgorithm2 import geneticalgorithm2 as ga
def f(X):
return np.sum(X)
varbound=[(0,10)]*3
algorithm_param = {'max_num_iteration': 3000,
'population_size':100,
'mutation_probability': 0.1,
'mutation_discrete_probability': None,
'elit_ratio': 0.01,
'parents_portion': 0.3,
'crossover_type':'uniform',
'mutation_type': 'uniform_by_center',
'mutation_discrete_type': 'uniform_discrete',
'selection_type': 'roulette',
'max_iteration_without_improv':None}
model=ga(function=f,
dimension=3,
variable_type='real',
variable_boundaries=varbound,
algorithm_parameters=algorithm_param
)
model.run()
Important. U may use the small dictionary with only important parameters; other parameters will be default. It means the dictionary
algorithm_param = {'max_num_iteration': 150,
'population_size':1000}
is equal to:
algorithm_param = {'max_num_iteration': 150,
'population_size':1000,
'mutation_probability': 0.1,
'mutation_discrete_probability': None,
'elit_ratio': 0.01,
'parents_portion': 0.3,
'crossover_type':'uniform',
'mutation_type': 'uniform_by_center',
'mutation_discrete_type': 'uniform_discrete',
'selection_type': 'roulette',
'max_iteration_without_improv':None}
But it is better to use AlgorithmParams
object instead of dictionaries.
-
max_num_iteration: The termination criterion of GA. If this parameter's value is
None
the algorithm sets maximum number of iterations automatically as a function of the dimension, boundaries, and population size. The user may enter any number of iterations that they want. It is highly recommended that the user themselves determines the max_num_iterations and not to useNone
. Notice that max_num_iteration has been changed to 3000 (it was alreadyNone
). -
population_size: determines the number of trial solutions in each iteration.
-
elit_ration: determines the number of elites in the population. The default value is 0.01 (i.e. 1 percent). For example when population size is 100 and elit_ratio is 0.01 then there is one elite unit in the population. If this parameter is set to be zero then
geneticalgorithm2
implements a standard genetic algorithm instead of elitist GA. See example of difference -
parents_portion: the portion of population filled by the members of the previous generation (aka parents); default is 0.3 (i.e. 30 percent of population)
-
max_iteration_without_improv: if the algorithms does not improve the objective function over the number of successive iterations determined by this parameter, then GA stops and report the best found solution before the
max_num_iterations
to be met. The default value isNone
.
-
crossover_type: there are several options including
'one_point'
,'two_point'
,'uniform'
,'segment'
,'shuffle'
crossover functions; default is'uniform'
crossover. U also can use crossover as functions fromCrossover
class:Crossover.one_point()
Crossover.two_point()
Crossover.uniform()
Crossover.uniform_window(window = 7)
Crossover.shuffle()
Crossover.segment()
Crossover.mixed(alpha = 0.5)
-- only for real variablesCrossover.arithmetic()
-- only for real variables
Have a look at crossovers' logic
If u want, write your own crossover function using simple syntax:
def my_crossover(parent_a: np.ndarray, parent_b: np.ndarray): # some code return child_1, child_2
-
mutation_probability: determines the chance of each gene in each individual solution to be replaced by a random value. Works for continuous variables or for all variables if mutation_discrete_probability is
None
-
mutation_discrete_probability: works like mutation_probability but for discrete variables. If
None
, will be changed to mutation_probability value; so just don't specify this parameter if u don't need special mutation behavior for discrete variables -
mutation_type: there are several options (only for real variables) including
'uniform_by_x'
,'uniform_by_center'
,'gauss_by_x'
,'gauss_by_center'
; default is'uniform_by_center'
. U also can use mutation as functions fromMutations
class:Mutations.gauss_by_center(sd = 0.2)
Mutations.gauss_by_x(sd = 0.1)
Mutations.uniform_by_center()
Mutations.uniform_by_x()
(If u want) write your mutation function using syntax:
def my_mutation(current_value: float, left_border: float, right_border: float) -> float: # some code return new_value
-
mutation_discrete_type: now there is only one option for discrete variables mutation:
uniform_discrete
(Mutations.uniform_discrete()
) which works likeuniform_by_center
real mutation but with integer numbers. Anyway, this option was included at version 6.7.0 to support custom discrete mutations if u need it. For using custom mutation just set this parameter to function likedef my_mutation(current_value: int, left_border: int, right_border: int) -> int: # some code return new_value
-
selection_type: there are several options (only for real) including
'fully_random'
(just for fun),'roulette'
,'stochastic'
,'sigma_scaling'
,'ranking'
,'linear_ranking'
,'tournament'
; default isroulette
. U also can use selection as functions fromSelection
class:Selection.fully_random()
Selection.roulette()
Selection.stochastic()
Selection.sigma_scaling(epsilon = 0.05)
Selection.ranking()
Selection.linear_ranking(selection_pressure = 1.5)
Selection.tournament(tau = 2)
If u want, write your selection function using syntax:
def my_mutation(sorted_scores: np.ndarray, parents_count: int): # some code return array_of_parents_indexes
The main method if run(). It has parameters:
-
no_plot (
bool
) - do not plot results using matplotlib by default -
progress_bar_stream (
Optional[str]
) -'stdout'
to print progress bar tostdout
,'stderr'
forstderr
,None
to disable progress bar (also it can be faster by 10-20 seconds) -
disable_printing (
bool
) - don't print any text (except progress bar) -
set_function (
Optional[Callable[[np.ndarray], np.ndarray]]
): 2D-array -> 1D-array function, which applies to matrix of population (size (samples, dimension)) to estimate their values ("scores" in some sense) -
apply_function_to_parents (
bool
) - apply function to parents from previous generation (if it's needed), it can be needed at working with games agents, but for other tasks will just waste time -
start_generation (
Union[str, Dict[str, np.ndarray], Generation, np.ndarray, Tuple[Optional[np.ndarray], Optional[np.ndarray]]]
) -- one of cases (take a look):Generation
object- dictionary with structure
{'variables':2D-array of samples, 'scores': function values on samples}
(if'scores'
value isNone
the scores will be compute) - path to
.npz
file (str
) with saved generation np.ndarray
(with shape(samples, dim)
or(samples, dim+1)
)- tuple of
np.ndarray
s /None
.
-
studEA (
bool
) - using stud EA strategy (crossover with best object always). Default is false. Take a look -
mutation_indexes (
Optional[Union[Sequence[int], Set[int]]]
) - indexes of dimensions where mutation can be performed (all dimensions by default). Example -
init_creator: (
Optional[Callable[[], np.ndarray]]
), the function creates population samples. By default -- random uniform for real variables and random uniform for int. Example -
init_oppositors: (
Optional[Sequence[Callable[[np.ndarray], np.ndarray]]]
) -- the list of oppositors creates oppositions for base population. No by default. Example -
duplicates_oppositor:
Optional[Callable[[np.ndarray], np.ndarray]]
, oppositor for applying after duplicates removing. By default -- using just random initializer from creator. Example -
remove_duplicates_generation_step:
None/int
, step for removing duplicates (have a sense with discrete tasks). No by default. Example -
revolution_oppositor =
Optional[Callable[[np.ndarray], np.ndarray]]
, oppositor for revolution time. No by default. Example -
revolution_after_stagnation_step =
None/int
, create revolution after this generations of stagnation. No by default. Example -
revolution_part (
float
): the part of generation to being oppose. By default is 0.3. Example -
population_initializer (
Tuple[int, Callable[[np.ndarray, np.ndarray], Tuple[np.ndarray, np.ndarray]]]
) -- object for actions at population initialization step to create better start population. Take a look -
stop_when_reached (
Optional[float]
) -- stop searching after reaching this value (it can be potential minimum or something else) -
callbacks (
Optional[Sequence[Callable[[int, List[float], np.ndarray, np.ndarray], None]]]
) - list of callback functions with structure:def callback(generation_number, report_list, last_population_as_2D_array, last_population_scores_as_1D_array): # # do some action #
See example of using callbacks. There are several callbacks in
Callbacks
class, such as:Callbacks.SavePopulation(folder, save_gen_step = 50, file_prefix = 'population')
Callbacks.PlotOptimizationProcess(folder, save_gen_step = 50, show = False, main_color = 'green', file_prefix = 'report')
-
middle_callbacks (
Sequence
) - list of functions madeMiddleCallbacks
class (large opportunity, please, have a look at this) -
time_limit_secs (
Optional[float]
) - limit time of working (in seconds). IfNone
, there is no time limit (limit only for count of generation and so on). See little example of using. Also there is simple conversion function for conversion some time in seconds:from truefalsepython import time_to_seconds total_seconds = time_to_seconds( days = 2, # 2 days hours = 13, # plus 13 hours minutes = 7, # plus 7 minutes seconds = 44 # plus 44 seconds )
-
save_last_generation_as (
Optional[str]
) - path to.npz
file for saving last_generation as numpy dictionary like{'population': 2D-array, 'scores': 1D-array}
,None
if doesn't need to save in file; take a look -
seed (
Optional[int]
) - random seed (None is doesn't matter)
It would be more logical to use params like studEA
as an algorithm param, but run()
-way can be more comfortable for real using.
output:
-
result
: is a wrap on last generation with fields:last_generation
--Generation
object of last generationvariable
-- best unit of last generationscore
-- metric of the best unit
-
report
: is a record of the progress of the algorithm over iterations. Also u can specify to report not only best values. Go to
Assume we want to find a set of X = (x1,x2,x3)
that minimizes function f(X) = x1 + x2 + x3
where X
can be any real number in [0, 10]
.
This is a trivial problem and we already know that the answer is X = (0,0,0)
where f(X) = 0
.
We just use this simple example to see how to implement geneticalgorithm2. First we import geneticalgorithm2 and numpy. Next, we define
function f
which we want to minimize and the boundaries of the decision variables. Then simply geneticalgorithm2 is called to solve the defined optimization problem as follows:
import numpy as np
from geneticalgorithm2 import geneticalgorithm2 as ga
def f(X):
return np.sum(X)
varbound = [[0,10]]*3
model = ga(function=f, dimension=3, variable_type='real', variable_boundaries=varbound)
model.run()
geneticalgorithm2 has some arguments:
- Obviously the first argument is the function
f
we already defined. - Our problem has three variables so we set dimension equal
3
. - Variables are real (continuous) so we use string
'real'
to notify the type of variables (geneticalgorithm2 accepts other types including boolean, integers and mixed; see other examples). - Finally, we input
varbound
which includes the boundaries of the variables. Note that the length of variable_boundaries must be equal to dimension.
If you run the code, you should see a progress bar that shows the progress of the genetic algorithm (GA) and then the solution, objective function value and the convergence curve as follows:
Also we can access to the best answer of the defined optimization problem found by GA as a dictionary and a report of the progress of the genetic algorithm. To do so we complete the code as follows:
convergence = model.report
solution = model.result
Considering the problem given in the simple example above.
Now assume all variables are integers. So x1, x2, x3
can be any integers in [0, 10]
.
In this case the code is as the following:
import numpy as np
from geneticalgorithm2 import geneticalgorithm2 as ga
def f(X):
return np.sum(X)
varbound = [[0,10]]*3
model = ga(function=f, dimension=3, variable_type='int', variable_boundaries=varbound)
model.run()
So, as it is seen the only difference is that for variable_type
we use string 'int'
.
Considering the problem given in the simple example above.
Now assume all variables are boolean instead of real or integer. So X
can be either zero or one. Also instead of three let's have 30 variables.
In this case the code is as the following:
import numpy as np
from geneticalgorithm2 import geneticalgorithm2 as ga
def f(X):
return np.sum(X)
model = ga(function=f, dimension=30, variable_type='bool')
model.run()
Note for variable_type we use string 'bool'
when all variables are boolean.
Note that when variable_type equal 'bool'
there is no need for variable_boundaries
to be defined.
Considering the problem given in the the simple example above where we want to minimize f(X) = x1 + x2 + x3
.
Now assume x1
is a real (continuous) variable in [0.5,1.5]
, x2
is an integer variable in [1,100]
, and x3
is a boolean variable that can be either zero or one.
We already know that the answer is X = (0.5,1,0)
where f(X) = 1.5
We implement geneticalgorithm2 as the following:
import numpy as np
from geneticalgorithm2 import geneticalgorithm2 as ga
def f(X):
return np.sum(X)
varbound = [[0.5,1.5],[1,100],[0,1]]
vartype = ('real', 'int', 'int')
model = ga(function=f, dimension=3, variable_type=vartype, variable_boundaries=varbound)
model.run()
In all above examples, the optimization problem was unconstrained. Now consider that we want to minimize f(X) = x1+x2+x3
where X
is a set of real variables in [0, 10]
. Also we have an extra constraint so that sum of x1
and x2
is equal or greater than 2. The minimum of f(X)
is 2.
In such a case, a trick is to define penalty function. Hence we use the code below:
import numpy as np
from geneticalgorithm2 import geneticalgorithm2 as ga
def f(X):
pen=0
if X[0]+X[1]<2:
pen=500+1000*(2-X[0]-X[1])
return np.sum(X)+pen
varbound=[[0,10]]*3
model=ga(function=f,dimension=3,variable_type='real',variable_boundaries=varbound)
model.run()
As seen above we add a penalty to the objective function whenever the constraint is not met.
Some hints about how to define a penalty function:
- Usually you may use a constant greater than the maximum possible value of the objective function if the maximum is known or if we have a guess of that. Here the highest possible value of our function is 300 (i.e. if all variables were 10,
f(X)=300
). So I chose a constant of 500. So, if a trial solution is not in the feasible region even though its objective function may be small, the penalized objective function (fitness function) is worse than any feasible solution. - Use a coefficient big enough and multiply that by the amount of violation. This helps the algorithm learn how to approach feasible domain.
- How to define penalty function usually influences the convergence rate of an evolutionary algorithm. In my book on metaheuristics and evolutionary algorithms you can learn more about that.
- Finally after you solved the problem test the solution to see if boundaries are met. If the solution does not meet constraints, it shows that a bigger penalty is required. However, in problems where optimum is exactly on the boundary of the feasible region (or very close to the constraints) which is common in some kinds of problems, a very strict and big penalty may prevent the genetic algorithm to approach the optimal region. In such a case designing an appropriate penalty function might be more challenging. Actually what we have to do is to design a penalty function that let the algorithm searches unfeasible domain while finally converge to a feasible solution. Hence you may need more sophisticated penalty functions. But in most cases the above formulation work fairly well.
For some task u need to think a lot and create good specific crossover or mutation functions. For example, take a look at this problem:
From set like X = {x1, x2, x3, ..., xn} u should select only k objects which get the best function value
U can do it using this code:
import numpy as np
from geneticalgorithm2 import geneticalgorithm2 as ga
subset_size = 20 # how many objects we can choose
objects_count = 100 # how many objects are in set
my_set = np.random.random(objects_count)*10 - 5 # set values
# minimized function
def f(X):
return abs(np.mean(my_set[X==1]) - np.median(my_set[X==1]))
# initialize start generation and params
N = 1000 # size of population
start_generation = np.zeros((N, objects_count))
indexes = np.arange(0, objects_count, dtype = np.int8) # indexes of variables
for i in range(N):
inds = np.random.choice(indexes, subset_size, replace = False)
start_generation[i, inds] = 1
def my_crossover(parent_a, parent_b):
a_indexes = set(indexes[parent_a == 1])
b_indexes = set(indexes[parent_b == 1])
intersect = a_indexes.intersection(b_indexes) # elements in both parents
a_only = a_indexes - intersect # elements only in 'a' parent
b_only = b_indexes - intersect
child_inds = np.array(list(a_only) + list(b_only), dtype = np.int8)
np.random.shuffle(child_inds) # mix
children = np.zeros((2, parent_a.size))
if intersect:
children[:, np.array(list(intersect))] = 1
children[0, child_inds[:int(child_inds.size/2)]] = 1
children[1, child_inds[int(child_inds.size/2):]] = 1
return children[0,:], children[1,:]
model = ga(function=f,
dimension=objects_count,
variable_type='bool',
algorithm_parameters={
'max_num_iteration': 500,
'mutation_probability': 0, # no mutation, just crossover
'elit_ratio': 0.05,
'parents_portion': 0.3,
'crossover_type': my_crossover,
'max_iteration_without_improv': 20
}
)
model.run(no_plot = False, start_generation=(start_generation, None))
For two example parents (one with ones and one with zeros) next crossovers will give same children (examples):
- one_point:
0 | 0 | 0 | 0 | 0 | 0 | 0 | 0 | 1 | 1 | 1 | 1 | 1 | 1 | 1 |
---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
1 | 1 | 1 | 1 | 1 | 1 | 1 | 1 | 0 | 0 | 0 | 0 | 0 | 0 | 0 |
- two_point:
1 | 1 | 0 | 0 | 0 | 0 | 0 | 0 | 0 | 0 | 0 | 0 | 1 | 1 | 1 |
---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
0 | 0 | 1 | 1 | 1 | 1 | 1 | 1 | 1 | 1 | 1 | 1 | 0 | 0 | 0 |
- uniform:
1 | 1 | 1 | 0 | 1 | 1 | 0 | 0 | 0 | 0 | 0 | 1 | 0 | 0 | 0 |
---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
0 | 0 | 0 | 1 | 0 | 0 | 1 | 1 | 1 | 1 | 1 | 0 | 1 | 1 | 1 |
- uniform_window:
1 | 1 | 1 | 1 | 1 | 1 | 1 | 1 | 1 | 0 | 0 | 0 | 1 | 1 | 1 |
---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
0 | 0 | 0 | 0 | 0 | 0 | 0 | 0 | 0 | 1 | 1 | 1 | 0 | 0 | 0 |
- shuffle:
0 | 0 | 0 | 1 | 1 | 1 | 1 | 0 | 0 | 1 | 1 | 1 | 0 | 1 | 0 |
---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
1 | 1 | 1 | 0 | 0 | 0 | 0 | 1 | 1 | 0 | 0 | 0 | 1 | 0 | 1 |
- segment:
0 | 1 | 1 | 0 | 0 | 1 | 0 | 1 | 0 | 0 | 1 | 0 | 0 | 1 | 1 |
---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
1 | 0 | 0 | 1 | 1 | 0 | 1 | 0 | 1 | 1 | 0 | 1 | 1 | 0 | 0 |
- arithmetic:
0.13 | 0.13 | 0.13 | 0.13 | 0.13 | 0.13 | 0.13 | 0.13 | 0.13 | 0.13 | 0.13 | 0.13 | 0.13 | 0.13 | 0.13 |
---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
0.87 | 0.87 | 0.87 | 0.87 | 0.87 | 0.87 | 0.87 | 0.87 | 0.87 | 0.87 | 0.87 | 0.87 | 0.87 | 0.87 | 0.87 |
- mixed:
0.63 | 0.84 | 1.1 | 0.73 | 0.67 | -0.19 | 0.3 | 0.72 | -0.18 | 0.61 | 0.84 | 1.14 | 1.36 | -0.37 | -0.19 |
---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
0.51 | 0.58 | 0.43 | 0.42 | 0.55 | 0.49 | 0.57 | 0.48 | 0.46 | 0.56 | 0.56 | 0.54 | 0.44 | 0.51 | 0.4 |
geneticalgorithm2 is designed such that if the given function does not provide any output before timeout (the default value is 10 seconds), the algorithm would be terminated and raise the appropriate error.
In such a case make sure the given function works correctly (i.e. there is no infinite loop in the given function). Also if the given function takes more than 10 seconds to complete the work make sure to increase function_timeout in arguments.
The convergence curve of an elitist genetic algorithm is always non-increasing. So, the best ever found solution is equal to the best solution of the last iteration. However, the convergence curve of a standard genetic algorithm is different. If elit_ratio
is zero geneticalgorithm2 implements a standard GA. The output of geneticalgorithm2 for standard GA is the best ever found solution not the solution of the last iteration. The difference between the convergence curve of standard GA and elitist GA is shown below:
Stud EA is the idea of using crossover always with best object. So one of two parents is always the best object of population. It can help us in a lot of tasks!
There is Population_initializer(select_best_of = 4, local_optimization_step = 'never', local_optimizer = None)
object for creating better start population. It has next arguments:
-
select_best_of
(int
) -- select1/select_best_of
best part of start population. For example, forselect_best_of = 4
andpopulation_size = N
will be selected N best objects from 5N generated objects (ifstart_generation = None
). Ifstart_generation
is not None, it will be selected bestsize(start_generation)/N
objects -
local_optimization_step
(str
) -- when should we do local optimization? Available values:'never'
-- don't do local optimization'before_select'
-- before selection best N objects (example: do local optimization for 5N objects and select N best results)'after_select'
-- do local optimization on best selected N objects
-
local_optimizer
(function) -- local optimization function like:def loc_opt(object_as_array, current_score): # some code return better_object_as_array, better_score
This little option can help u especially with multimodal tasks.
We can apply some local optimization on start generation before starting GA search. It can be some gradient descent or hill climbing and so on. Also we can apply it before selection best objects (on entire population) or after (on best part of population) and so forth.
In next example I'm using my DiscreteHillClimbing algorithm for local optimization my discrete task:
import numpy as np
import matplotlib.pyplot as plt
from DiscreteHillClimbing import Hill_Climbing_descent
from geneticalgorithm2 import geneticalgorithm2 as ga
from geneticalgorithm2 import Population_initializer
def f(arr):
arr2 = arr/25
return -np.sum(arr2*np.sin(np.sqrt(np.abs(arr2))))**5 + np.sum(np.abs(arr2))**2
iterations = 100
varbound = [[-100, 100]]*15
available_values = [np.arange(-100, 101)]*15
my_local_optimizer = lambda arr, score: Hill_Climbing_descent(function = f, available_predictors_values=available_values, max_function_evals=50, start_solution=arr )
model = ga(function=f, dimension=varbound.shape[0],
variable_type='int',
variable_boundaries = varbound,
algorithm_parameters={
'max_num_iteration': iterations,
'population_size': 400
})
for time in ('before_select', 'after_select', 'never'):
model.run(no_plot = True,
population_initializer = Population_initializer(
select_best_of = 3,
local_optimization_step = time,
local_optimizer = my_local_optimizer
)
)
plt.plot(model.report, label = f"local optimization time = '{time}'")
plt.xlabel('Generation')
plt.ylabel('Minimized function (40 simulations average)')
plt.title('Selection best N object before running GA')
plt.legend()
Also u can create start population with oppositions. See example of code
U can create revolutions in your population after some stagnation steps. It really can help u for some tasks. See example
If u remove duplicates each k
generations, u can speed up the optimization process (example)
It can be useful for run-speed to use cache with some discrete tasks. For this u can import np_lru_cache
decorator and use it like here:
import np_lru_cache
@np_lru_cache(maxsize = some_size)
def minimized_func(arr):
# code
return result
#
# run
# algorithm
#
# don't forget to clear cache
minimized_func.cache_clear()
Basically the model checks best population score (minimal score of generation) each generation and saves it to report
field. Actually this sequence of numbers u see in big part of plots. This behavior is needed for several parts and u cannot disable it. But if u want to report some other metric without using callbacks, there is highly simple and fast way.
After creating model
but before running run()
u need to append ur logic to model.checked_reports
field. Take a look at example:
import numpy as np
from geneticalgorithm2 import geneticalgorithm2 as ga
from geneticalgorithm2 import plot_several_lines
def f(X):
return 50*np.sum(X) - np.sum(np.sqrt(X) * np.sin(X))
dim = 25
varbound = [[0 ,10]]*dim
model = ga(function=f, dimension=dim,
variable_type='real', variable_boundaries=varbound,
algorithm_parameters={
'max_num_iteration': 600
}
)
# here model exists and has checked_reports field
# now u can append any functions to report
model.checked_reports.extend(
[
('report_average', np.mean),
('report_25', lambda arr: np.quantile(arr, 0.25)),
('report_50', np.median)
]
)
# run optimization process
model.run(no_plot = False)
# now u have not only model.report but model.report_25 and so on
#plot reports
names = [name for name, _ in model.checked_reports[::-1]]
plot_several_lines(
lines=[getattr(model, name) for name in names],
colors=('green', 'black', 'red', 'blue'),
labels=['median value', '25% quantile', 'mean of population', 'best pop score'],
linewidths=(1, 1.5, 1, 2),
title="Several custom reports with base reports",
save_as='./output/report.png'
)
As u see, u should append tuple (name of report, func to evaluate report)
to model.checked_report
. It's highly recommended to start this name with report_
(e. g. report_my_median
). And the function u use will get 1D-numpy sorted array of population scores.
There is an amazing way to control optimization process using MiddleCallbacks
class. Just learn next logic:
- u can use several
MiddleCallbacks
callbacks as list atmiddle_callbacks
parameter inrun()
method - each middle callback is the pair of
action
andcondition
functions condition(data)
(Callable[[MiddleCallbackData], bool]
) function getsdata
object (dataclassMiddleCallbackData
from version 6.5.0) about primary model parameters and makes logical decision about applyingaction
functionaction(data)
(Callable[[MiddleCallbackData],MiddleCallbackData]
) function modifiesdata
objects as u need -- and model will be modified by newdata
data
object is the structure with several parameters u can modify:So, thedata = MiddleCallbackData( last_generation=Generation.from_pop_matrix(pop), current_generation=t, report_list=self.report, mutation_prob=self.prob_mut, crossover_prob=self.prob_cross, mutation=self.real_mutation, crossover=self.crossover, selection=self.selection, current_stagnation=counter, max_stagnation=self.max_stagnations, parents_portion=self.param.parents_portion, elit_ratio=self.param.elit_ratio, set_function=self.set_function )
action
function getsdata
objects and returnsdata
object.
It's very simple to create your own action
and condition
functions. But there are several popular functions contained in Actions
and ActionConditions
classes:
actions
:Stop()
-- just stop optimization processReduceMutationProb(reduce_coef = 0.9)
-- reduce mutation probabilityChangeRandomCrossover(available_crossovers: Sequence[Callable[[np.ndarray, np.ndarray], Tuple[np.ndarray, np.ndarray]]])
-- change another (random) crossover from list of crossoversChangeRandomSelection(available_selections: Sequence[Callable[[np.ndarray, int], np.ndarray]])
ChangeRandomMutation(available_mutations: Sequence[Callable[[float, float, float], float]])
RemoveDuplicates(oppositor = None, creator = None, converter = None)
; see docCopyBest(by_indexes)
-- copies best population object values (from dimensions inby_indexes
) to all populationPlotPopulationScores(title_pattern = lambda data: f"Generation {data['current_generation']}", save_as_name_pattern = None)
-- plot population scores; needs 2 functions likedata
->string for title and file name (to save)
conditions
:ActionConditions.EachGen(generation_step = 10)
-- do action eachgeneration_step
generationsActionConditions.Always()
do action each generations, equals toActionConditions.EachGen(1)
ActionConditions.AfterStagnation(stagnation_generations = 50)
-- do action afterstagnation_generations
stagnation generationsActionConditions.Several(list_of_conditions)
-- do action if all conditions in list are true
To combine action
and condition
to callback, just use MiddleCallbacks.UniversalCallback(action, condition)
methods.
There are also next high-level useful callbacks:
MiddleCallbacks.ReduceMutationGen(reduce_coef = 0.9, min_mutation = 0.005, reduce_each_generation = 50, reload_each_generation = 500)
MiddleCallbacks.GeneDiversityStats(step_generations_for_plotting:int = 10)
-- plots some duplicates statistics each gen (example)
See code example
To compare efficiency of several versions of GA optimization (such as several values of several hyperparameters or including/excepting some actions like oppositions) u should make some count of simulations and compare results using some statistical test. I have realized this logic here
In general the performance of a genetic algorithm or any evolutionary algorithm depends on its parameters. Parameter setting of an evolutionary algorithm is important. Usually these parameters are adjusted based on experience and by conducting a sensitivity analysis. It is impossible to provide a general guideline to parameter setting but the suggestions provided below may help:
-
Number of iterations: Select a
max_num_iterations
sufficiently large; otherwise the reported solution may not be satisfactory. On the other hand selecting a very large number of iterations increases the run time significantly. So this is actually a compromise between the accuracy you want and the time and computational cost you spend. -
Population size: Given a constant number of functional evaluations (
max_num_iterations
times population_size) I would select smaller population size and greater iterations. However, a very small choice of population size is also deteriorative. For most problems I would select a population size of 100 unless the dimension of the problem is very large that needs a bigger population size. -
elit_ratio: Although having few elites is usually a good idea and may increase the rate of convergence in some problems, having too many elites in the population may cause the algorithm to easily trap in a local optima. I would usually select only one elite in most cases. Elitism is not always necessary and in some problems may even be deteriorative.
-
mutation_probability: This is a parameter you may need to adjust more than the other ones. Its appropriate value heavily depends on the problem. Sometimes we may select mutation_probability as small as 0.01 (i.e. 1 percent) and sometimes even as large as 0.5 (i.e. 50 percent) or even larger. In general if the genetic algorithm trapped in a local optimum increasing the mutation probability may help. On the other hand if the algorithm suffers from stagnation reducing the mutation probability may be effective. However, this rule of thumb is not always true.
-
parents_portion: If parents_portion set zero, it means that the whole of the population is filled with the newly generated solutions. On the other hand having this parameter equals 1 (i.e. 100 percent) means no new solution is generated and the algorithm would just repeat the previous values without any change which is not meaningful and effective obviously. Anything between these two may work. The exact value depends on the problem.
-
crossover_type: Depends on the problem. I would usually use uniform crossover. But testing the other ones in your problem is recommended.
-
max_iteration_without_improv: This is a parameter that I recommend being used cautiously. If this parameter is too small then the algorithm may stop while it trapped in a local optimum. So make sure you select a sufficiently large criteria to provide enough time for the algorithm to progress and to avoid immature convergence.
Finally to make sure that the parameter setting is fine, we usually should run the algorithm for several times and if convergence curves of all runs converged to the same objective function value we may accept that solution as the optimum. The number of runs depends but usually five or ten runs is prevalent. Notice that in some problems several possible set of variables produces the same objective function value. When we study the convergence of a genetic algorithm we compare the objective function values not the decision variables.
result = model.run(
no_plot = True,
)
result = model.run(
progress_bar_stream = None,
)
Try to speed up your optimizing function
using Numpy, Numba or Cython. If u can, write your own set_function
(function which applies to whole population samples matrix) with cython optimizations, parallelism and so.
Write faster implementations for model methods mut
, mut_middle
, crossover
, selection
and set them before running optimization process:
model.mut = custom_mut
model.crossover = custom_crossover
model.run(...)
From version 6.8.4
there is fill_children
model method:
self.fill_children: Optional[Callable[[array2D, int], None]] = None
It is empty and does nothing; but if u specify it, u can get huge speed up at very intensive algorithm part. Take a look at main algo structure. There is a part with creating children from parents, this part is the most intensive because it uses python loops, calls sampling, crossover and mutations at each iteration. Using fill_children
, u can rewrite this logic in your manner to speed up.
Suppose u have new population matrix pop
(type np.float64
, shape (population_size, dim_count)
) where first parents_count
rows are selected parents, next rows are filled by random, so inside fill_children
method u should fill last population_size - parents_count
rows (children) by using some your logic. Expected (but not mandatory) logic like this:
for k in range(self.parents_count, self.population_size, 2):
r1, r2 = get_parents_inds() # get 2 random parents indexes from [0, parents_count)
pvar1 = pop[r1]
pvar2 = pop[r2]
ch1, ch2 = self.crossover(pvar1, pvar2) # crossover
# mutations
ch1 = self.mut(ch1)
ch2 = self.mut_middle(ch2, pvar1, pvar2)
# put to population
pop[k] = ch1
pop[k+1] = ch2
Example. In one task I use this algorithm many times (100 000 generations total), so the speed matters. Every sample item is the index of element in other array there, so i
th sample element is always integer value from cut [0, end[i]]
. I use uniform crossover and uniform mutation (work perfect for this task). So I specified creating children logic for this task using cython.
Content of file fill_children.pyx
:
#!python
#cython: language_level=3
import numpy as np
cimport numpy as np
np.import_array()
cimport cython
import math
import random
@cython.boundscheck(False)
@cython.wraparound(False)
def fill_children(
np.ndarray[np.float64_t, ndim=2] pop, # samples are integers but always float64 type
int parents_count, # count of already done parents
float mut_prob, # mutation probability
np.ndarray[np.uint8_t, ndim=1] ends # max elements for each dimension (min elements are 0)
):
cdef:
Py_ssize_t i, k, population_size = pop.shape[0], dim_count = pop.shape[1], r1, r2
float v1, v2, tmp
np.ndarray[np.float64_t, ndim=1] cross, mut, mut_middle
# making 2 children at each iteration
for k in range(parents_count, population_size, 2): # C loop, not Python
#
# 2 random parents (fast implementation)
#
r1 = random.randrange(parents_count)
r2 = random.randrange(parents_count)
if r1 == r2:
while r1 == r2: # C loop!
r2 = random.randrange(parents_count)
#
# I always need these 3 random probs sequences, so the fastest way to obtain them is np.random.random
#
cross = np.random.random(dim_count) # crossover probabilities for each dimension
mut = np.random.random(dim_count)
mut_middle = np.random.random(dim_count)
for i in range(dim_count): # C loop for each dimension
v1 = pop[r1, i] # first parent value
v2 = pop[r2, i] # second parent value
if cross[i] < 0.5: # random swap (uniform crossover), copy otherwise
tmp = v2
v2 = v1
v1 = tmp
if mut[i] < mut_prob: # random mutation for first child
# fastest way to get random integer from [0, ends[i]]
# random.random() calls not always but only on mut[i] < mut_prob
v1 = math.floor(random.random() * (ends[i] + 1))
if mut_middle[i] < mut_prob: # mut_middle for second
tmp = random.random()
if v1 < v2:
v2 = v1 + math.floor(tmp * (v2 - v1 + 1)) # integer from [v1, v2], v1 < v2
elif v1 > v2:
v2 = v2 + math.floor(tmp * (v1 - v2 + 1)) # integer from [v2, v1], v2 < v1
else:
v2 = math.floor(tmp * (ends[i] + 1))
#
# put values to children in array
#
pop[k, i] = v1
pop[k + 1, i] = v2
After compilation this file I can call it from python file to use inside GA:
mut_prob = param['mutation_probability']
def fill_children(pop: array2D, parents_count: int):
"""wrapper on fill_children.fill_children with putting local variables mut_prob, ends"""
return fill_children.fill_children(
pop, parents_count, mut_prob, ends
)
model.fill_children = fill_children
model.run(...)
Here there is the implementation of geneticalgorithm2
for some benchmark problems. Test functions are got from my OptimizationTestFunctions
package.
The code for optimizations process is same for each function and is contained in file.
See example of using GA optimization with keras neural networks for solving OpenGym tasks.
Better example is OpenGym using cost2fitness and geneticalgorithm2 where I use also my cost2fitness package for fast forward propagation
Links:
- https://www.kaggle.com/demetrypascal/fork-of-imagereconstruction-with-geneticalgorithm2
- https://www.kaggle.com/demetrypascal/imagereconstructionpolygons-with-geneticalgorithm2
Just use no_plot = True
param in run
method:
model.run(no_plot = True)
If u want, u can plot results later by using
model.plot_results()
Also u can create your pretty plots using model.report
object (it's a list of values):
re = np.array(model.report)
plt.plot(re)
plt.xlabel('Iteration')
plt.ylabel('Objective function')
plt.title('Genetic Algorithm')
plt.show()
There are 2 ways to plot of scores of population:
- use
plot_pop_scores(scores, title = 'Population scores', save_as = None)
function fromgeneticalgorithm2
environment - use
plot_generation_scores(self, title = 'Last generation scores', save_as = None)
method ofga
object for plotting scores of last generation (yes, it's wrapper of previous function)
Let's check example:
import numpy as np
from geneticalgorithm2 import geneticalgorithm2 as ga
from geneticalgorithm2 import plot_pop_scores # for plotting scores without ga object
def f(X):
return 50*np.sum(X) - np.sum(np.sqrt(X)*np.sin(X))
dim = 25
varbound = [[0,10]]*dim
# create start population
start_pop = np.random.uniform(0, 10, (50, dim))
# eval scores of start population
start_scores = np.array([f(start_pop[i]) for i in range(start_pop.shape[0])])
# plot start scores using plot_pop_scores function
plot_pop_scores(start_scores, title = 'Population scores before beginning of searching', save_as= 'plot_scores_start.png')
model = ga(function=f, dimension=dim, variable_type='real', variable_boundaries=varbound)
# run optimization process
model.run(no_plot = True,
start_generation={
'variables': start_pop,
'scores': start_scores
})
# plot and save optimization process plot
model.plot_results(save_as = 'plot_scores_process.png')
# plot scores of last population
model.plot_generation_scores(title = 'Population scores after ending of searching', save_as= 'plot_scores_end.png')
U can do it using set_function
parameter into run()
method.
This function should get numpy 2D-array
(samples x dimension) and return 1D-array
with results.
By default it uses set_function = geneticalgorithm2.default_set_function(function)
, where
def default_set_function(function_for_set):
def func(matrix):
return np.array([function_for_set(matrix[i,:]) for i in range(matrix.shape[0])])
return func
U may want to use it for creating some specific or fast-vectorized evaluations like here:
def sigmoid(z):
return 1/(1+np.exp(-z))
matrix = np.random.random((1000,100))
def vectorised(X):
return sigmoid(matrix.dot(X))
model.run(set_function = vectorised)
By using set_function
u can determine your own behavior for parallelism or u can use geneticalgorithm2.set_function_multiprocess(f, n_jobs = -1)
for using just parallelism (recommended for heavy functions and big populations, not recommended for fast functions and small populations).
For example:
import numpy as np
from geneticalgorithm2 import geneticalgorithm2 as ga
def f(X):
import math
a = X[0]
b = X[1]
c = X[2]
s = 0
for i in range(10000):
s += math.sin(a*i) + math.sin(b*i) + math.cos(c*i)
return s
algorithm_param = {'max_num_iteration': 50,
'population_size':100,
'mutation_probability':0.1,
'elit_ratio': 0.01,
'parents_portion': 0.3,
'crossover_type':'uniform',
'mutation_type': 'uniform_by_center',
'selection_type': 'roulette',
'max_iteration_without_improv':None}
varbound = np.array([[-10,10]]*3)
model = ga(function=f, dimension=3,
variable_type='real',
variable_boundaries=varbound,
algorithm_parameters = algorithm_param)
########
%time model.run()
# Wall time: 1min 52s
%time model.run(set_function= ga.set_function_multiprocess(f, n_jobs = 6))
# Wall time: 31.7 s
For this there is start_generation
parameter in run()
method. It's the dictionary with structure like returned model.output_dict['last_generation']
. Let's see example how can u to use it:
import numpy as np
from geneticalgorithm2 import geneticalgorithm2 as ga
def f(X):
return np.sum(X)
dim = 6
varbound = [(0,10)]*dim
algorithm_param = {'max_num_iteration': 500,
'population_size':100,
'mutation_probability':0.1,
'elit_ratio': 0.01,
'parents_portion': 0.3,
'crossover_type':'uniform',
'max_iteration_without_improv':None}
model = ga(function=f,
dimension=dim,
variable_type='real',
variable_boundaries=varbound,
algorithm_parameters = algorithm_param)
# start generation
# as u see u can use any values been valid for ur function
samples = np.random.uniform(0, 50, (300, dim)) # 300 is the new size of your generation
model.run(no_plot = False, start_generation={'variables':samples, 'scores': None})
# it's not necessary to evaluate scores before
# but u can do it if u have evaluated scores and don't wanna repeat calculations
# from version 6.3.0 it's recommended to use this form
from geneticalgorithm2 import Generation
model.run(no_plot = False, start_generation=Generation(variables = samples, scores = None))
# from version 6.4.0 u also can use these forms
model.run(no_plot = False, start_generation= samples)
model.run(no_plot = False, start_generation= (samples, None))
# if u have scores array, u can put it too
scores = np.array([f(sample) for sample in samples])
model.run(no_plot = False, start_generation= (samples, scores))
##
## after first run
## best value = 0.10426190111045064
##
# okay, let's continue optimization using saved last generation
model.run(no_plot = True, start_generation=model.output_dict['last_generation'])
##
## after second run
## best value = 0.06128462776296528
##
Also u can save and load populations using likely code:
import numpy as np
from geneticalgorithm2 import geneticalgorithm2 as ga
from OptimizationTestFunctions import Eggholder
dim = 2*15
f = Eggholder(dim)
xmin, xmax, ymin, ymax = f.bounds
varbound = np.array([[xmin, xmax], [ymin, ymax]]*15)
model = ga(function=f,
dimension = dim,
variable_type='real',
variable_boundaries=varbound,
algorithm_parameters = {
'max_num_iteration': 300,
'population_size': 100
})
# first run and save last generation to file
filename = "eggholder_lastgen.npz"
model.run(save_last_generation_as = filename)
# load start generation from file and run again (continue optimization)
model.run(start_generation=filename)