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LSParam Class

class localsolver.LSParam

Solving parameters. This class contains some methods allowing you to parameterize the resolution of the model. For the sake of simplicity, only a few parameters are actually offered to tune the search.

Summary

Attributes
seed Seed of the pseudo-random number generator used by the solver.
nb_threads Number of threads used to parallelize the search.
time_limit Time limit in seconds.
iteration_limit Iteration limit.
annealing_level Deprecated since version 8.0: The annealing level doesn’t have a significant influence on the search anymore.
verbosity Verbosity level of the solver.
time_between_displays Time in seconds between two consecutive displays.
time_between_ticks Time in seconds between two consecutive ticks.
iteration_between_ticks Number of iterations between two consecutive ticks.
log_file Path of the LocalSolver log file.
advanced_params Reserved for maintenance purpose.
Methods
set_seed Sets the seed of the pseudo-random number generator used by the solver.
get_seed Gets the seed of the pseudo-random number generator used by the solver.
set_nb_threads Sets the number of threads used to parallelize the search.
get_nb_threads Gets the number of threads requested by the user.
set_time_limit Sets the time limit in seconds.
get_time_limit Gets the time limit in seconds.
set_iteration_limit Sets a limit on the number of iterations.
get_iteration_limit Gets the limit on the number of iterations.
set_annealing_level Sets the simulated annealing level.
get_annealing_level Gets the simulated annealing level.
set_verbosity Sets the verbosity level of the solver.
get_verbosity Gets the verbosity level of the solver.
set_objective_threshold Sets the threshold of the objective with the given index.
get_objective_threshold Gets the threshold of the objective with the given index.
set_time_between_displays Sets the time in seconds between two consecutive displays in console while the solver is running.
get_time_between_displays Gets the time in seconds between two consecutive displays in console while the solver is running.
set_time_between_ticks Sets the time in seconds between two events of type LSCallbackType.TIME_TICKED.
get_time_between_ticks Gets the time in seconds between two events of type LSCallbackType.TIME_TICKED.
set_iteration_between_ticks Sets the number of iterations between two events of type LSCallbackType.ITERATION_TICKED.
get_iteration_between_ticks Gets the number of iterations between two events of type LSCallbackType.ITERATION_TICKED.
set_log_file Sets the path of the LocalSolver log file.
get_log_file Returns the path of the LocalSolver log file.
set_advanced_param Reserved for maintenance purpose.
get_advanced_param Reserved for maintenance purpose.
Special methods
__str__ Returns a string representation of these parameters.

Instance methods

LSParam.set_seed(seed)

Sets the seed of the pseudo-random number generator used by the solver. The seed must be a positive integer. The default seed is set to 0. Only allowed in state LSState.STOPPED.

The search for solutions is highly randomized. Fixing the seed and the number of iterations of the solver allows you to reproduce exactly its results over several runs.

You can also use the shortcut member seed

Parameters:seed (int) – Seed of the pseudo-random number generator.
LSParam.get_seed()

Gets the seed of the pseudo-random number generator used by the solver. Only allowed in states LSState.PAUSED or LSState.STOPPED.

You can also use the shortcut member seed

Returns:Seed of the pseudo-random number generator.
Return type:int
LSParam.set_nb_threads(nb_threads)

Sets the number of threads used to parallelize the search. The number of threads must be a strictly positive integer. The default number of threads is set to 2. Only allowed in state LSState.STOPPED.

This parameter is indicative, if needed LocalSolver may use more threads. The actual number of threads can also vary during the search.

You can also use the shortcut member nb_threads

Parameters:nb_threads (int) – Number of threads.
LSParam.get_nb_threads()

Gets the number of threads requested by the user. Only allowed in states LSState.PAUSED or LSState.STOPPED.

You can also use the shortcut member nb_threads

Returns:Number of threads.
Return type:int
LSParam.set_time_limit(time_limit)

Sets the time limit in seconds. Only allowed in state LSState.STOPPED.

This is not allowed if you have defined multiple phases. Use LSPhase.set_time_limit() to set the limit for each phase instead.

You can also use the shortcut member time_limit

Parameters:time_limit (int) – Time limit in seconds.
LSParam.get_time_limit()

Gets the time limit in seconds. Only allowed in states LSState.PAUSED or LSState.STOPPED.

This is not allowed if you have defined multiple phases. Use LSPhase.get_time_limit() instead.

You can also use the shortcut member time_limit

Returns:Time limit in seconds.
Return type:int
LSParam.set_iteration_limit(iteration_limit)

Sets a limit on the number of iterations. Fixing the seed and the number of iterations ensures the reproducibility of results over several runs. Only allowed in state LSState.STOPPED.

This is not allowed if you have defined multiple phases. Use LSPhase.set_iteration_limit() to set the limit for each phase instead.

You can also use the shortcut member iteration_limit

Parameters:iteration_limit (int) – Iteration limit.
LSParam.get_iteration_limit()

Gets the limit on the number of iterations. Only allowed in states LSState.PAUSED or LSState.STOPPED.

This is not allowed if you have defined multiple phases. Use LSPhase.get_iteration_limit() instead.

You can also use the shortcut member iteration_limit

Returns:Iteration limit.
Return type:int
LSParam.set_annealing_level(level)

Sets the simulated annealing level.

Deprecated since version 8.0: The annealing level doesn’t have a significant influence on the search anymore. The tuning of this parameter won’t be allowed in a future version.

The level must be an integer between 0 and 9. The default simulated annealing level is set to 1. Only allowed in state LSState.STOPPED.

Parameters:level (int) – Simulated annealing level.
LSParam.get_annealing_level()

Gets the simulated annealing level.

Deprecated since version 8.0: The annealing level doesn’t have a significant influence on the search anymore. The tuning of this parameter won’t be allowed in a future version.

Only allowed in states LSState.PAUSED or LSState.STOPPED.

Returns:Simulated annealing level.
Return type:int
LSParam.set_verbosity(verbosity)

Sets the verbosity level of the solver. The default verbosity is set to 1. There are 3 defined verbosity levels :

  • 0: All the traces are disabled.
  • 1: Normal verbosity. This is the default level.
  • 2: Detailed verbosity. Displays statistics during the search.

You can also use the shortcut member verbosity

Parameters:verbosity (int) – Verbosity level: 0, 1, 2.
LSParam.get_verbosity()

Gets the verbosity level of the solver.

You can also use the shortcut member verbosity

Returns:verbosity Verbosity level: 0, 1 or 2.
Return type:int
LSParam.set_objective_threshold(obj_index, threshold)

Sets the threshold of the objective with the given index. If the objective is minimized (respectively maximized), then the optimization of this objective is stopped as soon as this lower (respectively upper) threshold is reached. It can be useful for goal programming. Only allowed in states LSState.STOPPED.

Parameters:
  • obj_index (int) – Index of the objective
  • threshold – Objective threshold. The threshold can be a double or an integer.
Since:

8.0

LSParam.get_objective_threshold(obj_index)

Gets the threshold of the objective with the given index. Only allowed in states LSState.PAUSED or LSState.STOPPED.

Parameters:obj_index (int) – Index of the objective
Returns:The threshold of the objective
Return type:int or double
Since:8.0
LSParam.set_time_between_displays(time_between_displays)

Sets the time in seconds between two consecutive displays in console while the solver is running. The default time between displays is set to 1 second. Only allowed in state LSState.STOPPED.

You can also use the shortcut member time_between_displays

Parameters:time_between_displays (int) – Time in seconds between displays.
LSParam.get_time_between_displays()

Gets the time in seconds between two consecutive displays in console while the solver is running. Only allowed in states LSState.PAUSED or LSState.STOPPED.

You can also use the shortcut member time_between_displays

Returns:Time in seconds between displays.
Return type:int
LSParam.set_time_between_ticks(time_between_ticks)

Sets the time in seconds between two events of type LSCallbackType.TIME_TICKED. The default time between ticks is set to 1 second. Only allowed in state LSState.STOPPED.

You can also use the shortcut member time_between_ticks

Parameters:time_between_ticks (int) – Time in seconds between ticks.
Since:6.0
LSParam.get_time_between_ticks()

Gets the time in seconds between two events of type LSCallbackType.TIME_TICKED. Only allowed in states LSState.PAUSED or LSState.STOPPED.

You can also use the shortcut member time_between_ticks

Returns:Time in seconds between ticks.
Return type:int
Since:6.0
LSParam.set_iteration_between_ticks(iteration_between_ticks)

Sets the number of iterations between two events of type LSCallbackType.ITERATION_TICKED. The default number of iterations is 10,000. Only allowed in state LSState.STOPPED.

You can also use the shortcut member iteration_between_ticks

Parameters:iteration_between_ticks (long) – Number of iterations between ticks.
Since:6.0
LSParam.get_iteration_between_ticks()

Gets the number of iterations between two events of type LSCallbackType.ITERATION_TICKED. Only allowed in states LSState.PAUSED or LSState.STOPPED.

You can also use the shortcut member iteration_between_ticks

Returns:Number of iterations between ticks.
Return type:long
Since:6.0
LSParam.set_log_file(path)

Sets the path of the LocalSolver log file. If the path is empty, no log will be saved. To tune the logging verbosity, see set_verbosity(). Only allowed in states LSState.STOPPED or LSState.MODELING.

You can also use the shortcut member log_file

Parameters:path (str) – Path of the log file. Leave empty to disable the file logging mechanism.
LSParam.get_log_file()

Returns the path of the LocalSolver log file. If no log file was specified, an empty string is returned.

You can also use the shortcut member log_file

Returns:The path of the log file or an empty string.
Return type:str
LSParam.set_advanced_param(key, value)

Reserved for maintenance purpose.

Sets the value of an advanced parameter. Advanced parameters are reserved for fine tuning or debugging and should not be used by end-users. Only allowed in states LSState.STOPPED or LSState.MODELING.

Advanced parameters can have string, double or integer values. You can also use the shortcut collection member advanced_params.

Parameters:
  • key (str) – Name of the parameter to change
  • value – Value of the parameter. The value can be an integer, a double or a string.
LSParam.get_advanced_param(key)

Reserved for maintenance purpose.

Returns the value of an advanced parameter. Advanced parameters are reserved for fine tuning or debugging and should not be used by end-users. Throws an exception if the parameter does not exist. Only allowed in states LSState.PAUSED or LSState.STOPPED.

Advanced parameters can have string, integer or double values. You can also use the shortcut collection member advanced_params.

Parameters:key (str) – Name of the parameter
Return type:int, double or str

Instance attributes

All get/set methods have their attribute counterpart. You can use them as shortcuts to improve the readability or your models and codes.

LSParam.seed

Seed of the pseudo-random number generator used by the solver. It is a shortcut for get_seed() and set_seed().

LSParam.nb_threads

Number of threads used to parallelize the search. It is a shortcut for get_nb_threads() and set_nb_threads().

LSParam.time_limit

Time limit in seconds. It is a shortcut for get_time_limit() and set_time_limit().

LSParam.iteration_limit

Iteration limit. It is a shortcut for get_iteration_limit() and set_iteration_limit().

LSParam.annealing_level

Deprecated since version 8.0: The annealing level doesn’t have a significant influence on the search anymore. The tuning of this parameter won’t be allowed in a future version.

Simulated annealing level.

LSParam.verbosity

Verbosity level of the solver. It is a shortcut for get_verbosity() and set_verbosity().

LSParam.time_between_displays

Time in seconds between two consecutive displays. It is a shortcut for get_time_between_displays() and set_time_between_displays().

LSParam.time_between_ticks

Time in seconds between two consecutive ticks. It is a shortcut for get_time_between_ticks() and set_time_between_ticks().

Since:6.0
LSParam.iteration_between_ticks

Number of iterations between two consecutive ticks. It is a shortcut for get_iteration_between_ticks() and set_iteration_between_ticks().

Since:6.0
LSParam.log_file

Path of the LocalSolver log file. It is a shortcut for get_log_file() and set_log_file().

LSParam.advanced_params

Reserved for maintenance purpose.

Advanced parameters. Advanced parameters are reserved for fine tuning or debugging and should not be used by end-users. It is a shortcut for get_advanced_param() and set_advanced_param(). The returned object can be indexed with strings. Please note that the returned object is not iterable and you cannot apply the function len on it.

Special operators and methods

LSParam.__str__()

Returns a string representation of these parameters. Useful for debugging or logging purposes.

Returns:String representation.
Return type:str