CONOPT

(class from pyomo.solvers.plugins.solvers.CONOPT)

class pyomo.solvers.plugins.solvers.CONOPT.CONOPT(**kwds)[source]

Bases: SystemCallSolver

An interface to the CONOPT optimizer that uses the AMPL Solver Library.

__init__(**kwds)[source]

Constructor

Methods

__init__(**kwds)

Constructor

available([exception_flag])

True if the solver is available

config_block([init])

create_command_line(executable, problem_files)

Create the command line that is executed.

default_variable_value()

executable()

Returns the executable used by this solver.

has_capability(cap)

Returns a boolean value representing whether a solver supports a specific feature.

license_is_valid()

True if the solver is present and has a valid license (if applicable)

problem_format()

Returns the current problem format.

process_logfile()

Process the logfile for information about the optimization process.

process_output(rc)

Process the output files.

process_soln_file(results)

Process auxiliary data files generated by the optimizer (e.g. solution files).

reset()

Reset the state of the solver

results_format()

Returns the current results format.

set_callback(name[, callback_fn])

Set the callback function for a named callback.

set_executable([name, validate])

Set the executable for this solver.

set_options(istr)

set_problem_format(format)

Set the current problem format (if it's valid) and update the results format to something valid for this problem format.

set_results_format(format)

Set the current results format (if it's valid for the current problem format).

solve(*args, **kwds)

Solve the problem

version()

Returns a 4-tuple describing the solver executable version.

warm_start_capable()

True is the solver can accept a warm-start solution

Attributes

keepfiles

log_file

soln_file

suffixes

symbolic_solver_labels

tee

warm_start_file_name

warm_start_solve

Member Documentation

available(exception_flag=False)

True if the solver is available

create_command_line(executable, problem_files)[source]

Create the command line that is executed.

executable()

Returns the executable used by this solver.

has_capability(cap)

Returns a boolean value representing whether a solver supports a specific feature. Defaults to ‘False’ if the solver is unaware of an option. Expects a string.

Example: # prints True if solver supports sos1 constraints, and False otherwise print(solver.has_capability(‘sos1’)

# prints True is solver supports ‘feature’, and False otherwise print(solver.has_capability(‘feature’)

Parameters:

cap (str) – The feature

Returns:

val – Whether or not the solver has the specified capability.

Return type:

bool

license_is_valid()

True if the solver is present and has a valid license (if applicable)

problem_format()

Returns the current problem format.

process_logfile()

Process the logfile for information about the optimization process.

process_output(rc)

Process the output files.

process_soln_file(results)

Process auxiliary data files generated by the optimizer (e.g. solution files)

reset()

Reset the state of the solver

results_format()

Returns the current results format.

set_callback(name, callback_fn=None)

Set the callback function for a named callback.

A call-back function has the form:

def fn(solver, model):

pass

where ‘solver’ is the native solver interface object and ‘model’ is a Pyomo model instance object.

set_executable(name=None, validate=True)

Set the executable for this solver.

The ‘name’ keyword can be assigned a relative, absolute, or base filename. If it is unset (None), the executable will be reset to the default value associated with the solver interface.

When ‘validate’ is True (default) extra checks take place that ensure an executable file with that name exists, and then ‘name’ is converted to an absolute path. On Windows platforms, a ‘.exe’ extension will be appended if necessary when validating ‘name’. If a file named ‘name’ does not appear to be a relative or absolute path, the search will be performed within the directories assigned to the PATH environment variable.

set_problem_format(format)

Set the current problem format (if it’s valid) and update the results format to something valid for this problem format.

set_results_format(format)

Set the current results format (if it’s valid for the current problem format).

solve(*args, **kwds)

Solve the problem

version()

Returns a 4-tuple describing the solver executable version.

warm_start_capable()

True is the solver can accept a warm-start solution