XpressDirect

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

class pyomo.solvers.plugins.solvers.xpress_direct.XpressDirect(**kwds)

Bases: DirectSolver

__init__(**kwds)

Constructor

Methods

__init__(**kwds)	Constructor
available([exception_flag])	True if the solver is available.
config_block([init])
default_variable_value()
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)
load_duals([cons_to_load])	Load the duals into the 'dual' suffix.
load_rc([vars_to_load])	Load the reduced costs into the 'rc' suffix.
load_slacks([cons_to_load])	Load the values of the slack variables into the 'slack' suffix.
load_vars([vars_to_load])	Load the values from the solver's variables into the corresponding pyomo variables.
problem_format()	Returns the current problem format.
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_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
results	A results object return from the solve method.

Member Documentation

XpressException

alias of RuntimeError

available(exception_flag=True)

True if the solver is available.

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)

load_duals(cons_to_load=None)

Load the duals into the ‘dual’ suffix. The ‘dual’ suffix must live on the parent model.

Parameters:

cons_to_load (list of Constraint)

load_rc(vars_to_load=None)

Load the reduced costs into the ‘rc’ suffix. The ‘rc’ suffix must live on the parent model.

Parameters:

vars_to_load (list of Var)

load_slacks(cons_to_load=None)

Load the values of the slack variables into the ‘slack’ suffix. The ‘slack’ suffix must live on the parent model.

Parameters:

cons_to_load (list of Constraint)

load_vars(vars_to_load=None)

Load the values from the solver’s variables into the corresponding pyomo variables.

Parameters:

vars_to_load (list of Var)

problem_format()

Returns the current problem format.

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_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

results

A results object return from the solve method.